Fix for bug 2283 (RVCT 4.0 support is missing from PDK 3.0.h)
Have multiple extension sections in the bld.inf, one for each version
of the compiler. The RVCT version building the tools will build the
runtime libraries for its version, but make sure we extract all the other
versions from zip archives. Also add the archive for RVCT4.
// Copyright (c) 2005-2009 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/buffer/t_hashtab.cpp
//
//
#include <e32test.h>
#include <e32hashtab.h>
#include <hal.h>
#if defined(__VC32__) || defined(__CW32__)
typedef unsigned short wch;
#else
typedef wchar_t wch;
#endif
RTest test(_L("T_HASHTAB"));
TInt NanoTickPeriod;
typedef TBuf8<80> TTestName;
typedef RHashSet<TInt> TIntSet;
typedef RHashSet<TTestName> TNameSet;
typedef RPtrHashSet<TDesC8> TStringSet8;
typedef RPtrHashSet<TDesC16> TStringSet16;
typedef RPtrHashMap<TDesC8,TDesC8> TStringMap8;
typedef RPtrHashMap<TDesC16,TDesC16> TStringMap16;
#define INTSET(x) TIntSet x
#define NAMESET(x) TNameSet x(&HashTestName, &TestNameIdentity)
#define STRSET8(x) TStringSet8 x
#define STRSET16(x) TStringSet16 x
#define STRMAP8(x) TStringMap8 x
#define STRMAP16(x) TStringMap16 x
RPointerArray<TDesC8> DesC8Array;
RPointerArray<TDesC16> DesC16Array;
class HashTest : public RHashTableBase
{
public:
HashTest() : RHashTableBase(0,0,0,0) {}
using RHashTableBase::ConsistencyCheck;
using RHashTableBase::Count;
};
void CCheck(RHashTableBase& aHT)
{
TUint32 ci[1024];
TUint32 dc;
TUint32 cmp;
HashTest* h = (HashTest*)&aHT;
h->ConsistencyCheck(&dc, &cmp, 1024, ci);
test.Printf(_L("Count = %d, Deleted = %d, Cmp = %d\n"), h->Count(), dc, cmp);
TInt i;
for (i=0; i<1024; ++i)
{
if (ci[i])
test.Printf(_L("%d chains of length %d\n"), ci[i], i);
}
}
const char* Numbers[] =
{
"zero",
"one",
"two",
"three",
"four",
"five",
"six",
"seven",
"eight",
"nine",
"ten",
"eleven",
"twelve",
"thirteen",
"fourteen",
"fifteen",
"sixteen",
"seventeen",
"eighteen",
"nineteen",
"twenty",
"thirty",
"forty",
"fifty",
"sixty",
"seventy",
"eighty",
"ninety",
"hundred",
"thousand"
};
TTestName NumberInWords(const TInt& aNum)
{
TInt a = aNum;
TTestName n;
if (a<20)
{
n.Copy((const TUint8*)Numbers[a]);
return n;
}
if (a<100)
{
TInt tens = a/10;
TInt units = a%10;
n.Copy((const TUint8*)Numbers[tens-2+20]);
if (units)
{
n.Append(' ');
n.Append(TPtrC8((const TUint8*)Numbers[units]));
}
return n;
}
if (a<1000)
{
TInt h = a/100;
n.Copy((const TUint8*)Numbers[h]);
n.Append(' ');
n.Append(TPtrC8((const TUint8*)Numbers[28]));
a%=100;
if (a)
{
TTestName n2(NumberInWords(a));
n.Append(_L8(" and "));
n+=n2;
}
return n;
}
TInt t = a/1000;
n = NumberInWords(t);
n.Append(' ');
n.Append(TPtrC8((const TUint8*)Numbers[29]));
a%=1000;
if (a)
{
TTestName n2(NumberInWords(a));
if (a<100)
n.Append(_L8(" and "));
else
n.Append(' ');
n+=n2;
}
return n;
}
void PrintNumberInWords(TInt a)
{
TBuf<256> buf;
TTestName n(NumberInWords(a));
buf.Copy(n);
test.Printf(_L("%d: %S\n"), a, &buf);
}
TUint32 HashTestName(const TTestName& aN)
{
return DefaultHash::Des8(aN);
}
TBool TestNameIdentity(const TTestName& aA, const TTestName& aB)
{
return aA == aB;
}
/******************************************************************************
* Utility functions for RHashSet<T>
******************************************************************************/
template <class T>
void Union(RHashSet<T>& aD, const RHashSet<T>& aS)
{
TInt c = aS.Count();
TInt c2 = c;
TInt d0 = aD.Count();
TInt d1 = d0;
typename RHashSet<T>::TIter iS(aS);
FOREVER
{
const T* p = iS.Next();
if (!p)
break;
--c2;
TInt r = aD.Insert(*p);
test(r==KErrNone);
++d1;
}
test(d1 == aD.Count());
test(c2 == 0);
}
template <class T>
void Subtract(RHashSet<T>& aD, const RHashSet<T>& aS)
{
TInt c = aS.Count();
TInt c2 = c;
TInt d0 = aD.Count();
TInt d1 = d0;
TInt nfd = 0;
typename RHashSet<T>::TIter iS(aS);
FOREVER
{
const T* p = iS.Next();
if (!p)
break;
--c2;
TInt r = aD.Remove(*p);
test(r==KErrNone || r==KErrNotFound);
if (r==KErrNotFound)
++nfd;
else
--d1;
}
test(d1 == aD.Count());
test(c2 == 0);
test( (d0-d1) + nfd == c);
}
template <class T>
void Intersect(RHashSet<T>& aD, const RHashSet<T>& aS)
{
typename RHashSet<T>::TIter iD(aD);
FOREVER
{
const T* p = iD.Next();
if (!p)
break;
if (!aS.Find(*p))
iD.RemoveCurrent();
}
}
template <class T>
void CheckIdentical(const RHashSet<T>& aA, const RHashSet<T>& aB)
{
test(aA.Count()==aB.Count());
TInt c = aA.Count();
typename RHashSet<T>::TIter iA(aA);
FOREVER
{
const T* p = iA.Next();
if (!p)
break;
--c;
test(aB.Find(*p)!=0);
}
test(c==0);
c = aA.Count();
typename RHashSet<T>::TIter iB(aB);
FOREVER
{
const T* p = iB.Next();
if (!p)
break;
--c;
test(aA.Find(*p)!=0);
}
test(c==0);
}
/******************************************************************************
* Utility functions for RPtrHashSet<T>
******************************************************************************/
template <class T>
void Union(RPtrHashSet<T>& aD, const RPtrHashSet<T>& aS)
{
TInt c = aS.Count();
TInt c2 = c;
TInt d0 = aD.Count();
TInt d1 = d0;
typename RPtrHashSet<T>::TIter iS(aS);
FOREVER
{
const T* p = iS.Next();
if (!p)
break;
--c2;
TInt r = aD.Insert(p);
test(r==KErrNone);
++d1;
}
test(d1 == aD.Count());
test(c2 == 0);
}
template <class T>
void Subtract(RPtrHashSet<T>& aD, const RPtrHashSet<T>& aS)
{
TInt c = aS.Count();
TInt c2 = c;
TInt d0 = aD.Count();
TInt d1 = d0;
TInt nfd = 0;
typename RPtrHashSet<T>::TIter iS(aS);
FOREVER
{
const T* p = iS.Next();
if (!p)
break;
--c2;
TInt r = aD.Remove(p);
test(r==KErrNone || r==KErrNotFound);
if (r==KErrNotFound)
++nfd;
else
--d1;
}
test(d1 == aD.Count());
test(c2 == 0);
test( (d0-d1) + nfd == c);
}
template <class T>
void Intersect(RPtrHashSet<T>& aD, const RPtrHashSet<T>& aS)
{
typename RPtrHashSet<T>::TIter iD(aD);
FOREVER
{
const T* p = iD.Next();
if (!p)
break;
if (!aS.Find(*p))
iD.RemoveCurrent();
}
}
template <class T>
void CheckIdentical(const RPtrHashSet<T>& aA, const RPtrHashSet<T>& aB)
{
test(aA.Count()==aB.Count());
TInt c = aA.Count();
typename RPtrHashSet<T>::TIter iA(aA);
FOREVER
{
const T* p = iA.Next();
if (!p)
break;
--c;
test(aB.Find(*p)!=0);
}
test(c==0);
c = aA.Count();
typename RPtrHashSet<T>::TIter iB(aB);
FOREVER
{
const T* p = iB.Next();
if (!p)
break;
--c;
test(aA.Find(*p)!=0);
}
test(c==0);
}
/******************************************************************************
* Utility functions for RHashMap<K,V>
******************************************************************************/
template <class K, class V>
void UnionTransform(RHashMap<K,V>& aD, const RHashSet<K>& aS, V (*aTransform)(const K&) )
{
TInt c = aS.Count();
TInt c2 = c;
TInt d0 = aD.Count();
TInt d1 = d0;
typename RHashSet<K>::TIter iS(aS);
FOREVER
{
const K* p = iS.Next();
if (!p)
break;
--c2;
TInt r = aD.Insert(*p, (*aTransform)(*p) );
test(r==KErrNone);
++d1;
}
test(d1 == aD.Count());
test(c2 == 0);
}
template <class K, class V>
void UnionMap(RHashSet<V>& aD, const RHashSet<K>& aS, const RHashMap<K,V>& aM)
{
TInt c = aS.Count();
TInt c2 = c;
TInt d0 = aD.Count();
TInt d1 = d0;
typename RHashSet<K>::TIter iS(aS);
FOREVER
{
const K* p = iS.Next();
if (!p)
break;
--c2;
const V* q = aM.Find(*p);
if (!q)
continue;
TInt r = aD.Insert(*q);
test(r==KErrNone);
++d1;
}
test(d1 == aD.Count());
test(c2 == 0);
}
template <class K, class V>
void UnionKeys(RHashSet<K>& aD, const RHashMap<K,V>& aM)
{
typename RHashMap<K,V>::TIter iM(aM);
FOREVER
{
const K* p = iM.NextKey();
if (!p)
break;
aD.Insert(*p);
}
}
template <class K, class V>
void UnionValues(RHashSet<V>& aD, const RHashMap<K,V>& aM)
{
typename RHashMap<K,V>::TIter iM(aM);
FOREVER
{
const K* p = iM.NextKey();
if (!p)
break;
const V* q = iM.CurrentValue();
aD.Insert(*q);
}
}
template <class K, class V>
void UnionTransform(RHashMap<K,V>& aD, const RHashMap<K,V>& aS, V (*aTransform)(const V&) )
{
TInt c = aS.Count();
TInt c2 = c;
TInt d0 = aD.Count();
TInt d1 = d0;
typename RHashMap<K,V>::TIter iS(aS);
FOREVER
{
const K* p = iS.NextKey();
if (!p)
break;
--c2;
TInt r = aD.Insert(*p, (*aTransform)(*iS.CurrentValue()) );
test(r==KErrNone);
++d1;
}
test(d1 == aD.Count());
test(c2 == 0);
}
template <class K, class V>
void UnionInverse(RHashMap<V,K>& aD, const RHashMap<K,V>& aS)
{
TInt c = aS.Count();
TInt c2 = c;
TInt d0 = aD.Count();
TInt d1 = d0;
typename RHashMap<K,V>::TIter iS(aS);
FOREVER
{
const K* p = iS.NextKey();
if (!p)
break;
--c2;
const V* q = iS.CurrentValue();
TInt r = aD.Insert(*q, *p);
test(r==KErrNone);
++d1;
}
test(d1 == aD.Count());
test(c2 == 0);
}
template <class K, class V>
void SetMap(RHashMap<V,K>& aM, const V& aV)
{
typename RHashMap<K,V>::TIter iM(aM);
FOREVER
{
const K* p = iM.NextKey();
if (!p)
break;
V* q = iM.CurrentValue();
*q = aV;
test(*q == aV);
}
}
/******************************************************************************
* Utility functions for RPtrHashMap<K,V>
******************************************************************************/
template <class K, class V>
void UnionTransform(RPtrHashMap<K,V>& aD, const RPtrHashMap<K,V>& aS, V* (*aTransform)(const V*) )
{
TInt c = aS.Count();
TInt c2 = c;
TInt d0 = aD.Count();
TInt d1 = d0;
typename RPtrHashMap<K,V>::TIter iS(aS);
FOREVER
{
const K* p = iS.NextKey();
if (!p)
break;
--c2;
TInt r = aD.Insert(p, (*aTransform)(iS.CurrentValue()) );
test(r==KErrNone);
++d1;
}
test(d1 == aD.Count());
test(c2 == 0);
}
template <class A, class B>
void UnionInverse(RPtrHashMap<B,A>& aD, const RPtrHashMap<A,B>& a1)
{
typename RPtrHashMap<A,B>::TIter iter(a1);
const A* pA;
while ( (pA=iter.NextKey()) != 0 )
{
const B* pB = iter.CurrentValue();
TInt r = aD.Insert(pB, pA);
test(r==KErrNone);
}
}
template <class A, class B, class C>
void UnionCompose(RPtrHashMap<A,C>& aD, const RPtrHashMap<A,B>& a1, const RPtrHashMap<B,C>& a2)
{
typename RPtrHashMap<A,B>::TIter iter(a1);
const A* pA;
while ( (pA=iter.NextKey()) != 0 )
{
const B* pB = iter.CurrentValue();
const C* pC = a2.Find(*pB);
if (pC)
{
TInt r = aD.Insert(pA, pC);
test(r==KErrNone);
}
}
}
template <class K, class V>
void CheckIdenticalMaps(const RPtrHashMap<K,V>& aA, const RPtrHashMap<K,V>& aB)
{
test(aA.Count()==aB.Count());
TInt c = aA.Count();
const K* p;
const V* q;
typename RPtrHashMap<K,V>::TIter iA(aA);
while( (p=iA.NextKey()) != 0)
{
--c;
q = aB.Find(*p);
test(q && q==iA.CurrentValue());
}
test(c==0);
c = aB.Count();
typename RPtrHashMap<K,V>::TIter iB(aB);
while( (p=iB.NextKey()) != 0)
{
--c;
q = aA.Find(*p);
test(q && q==iB.CurrentValue());
}
test(c==0);
}
/******************************************************************************
* Tests of TIntSet
******************************************************************************/
void Populate(TIntSet& aH, TInt aS, TInt aE, TInt aM)
{
TInt x = aS;
for (; x<=aE; x+=aM)
aH.Insert(x);
}
void PrimeSieve(TIntSet& aH, TInt aStart, TInt aEnd)
{
TInt x;
TInt e = (aEnd&1) ? aEnd : aEnd-1;
TInt s = (aStart<2) ? 2 : aStart|1;
for (x=s; x<=e; ++x)
{
// test.Printf(_L("add %d\n"),x);
aH.Insert(x);
}
TInt m=2;
FOREVER
{
for (; m*m<=e && !aH.Find(m); ++m)
{}
if (m*m > e)
break;
for (x=m*2; x<=e; x+=m)
{
// test.Printf(_L("remove %d\n"),x);
aH.Remove(x);
}
++m;
}
}
TBool IsPrime(TInt x)
{
if (x==2)
return ETrue;
if (!(x&1))
return EFalse;
TInt d;
for (d=3; d*d<=x; d+=2)
{
if (x%d==0)
return EFalse;
}
return ETrue;
}
void CheckSieveOutput(TIntSet& aH)
{
RHashSet<TInt>::TIter iter(aH);
TInt min = KMaxTInt;
TInt max = KMinTInt;
TInt c = 0;
test.Printf(_L("%d elements:\n"),aH.Count());
FOREVER
{
const TInt* p = iter.Next();
if (!p)
break;
++c;
if (*p>max) max=*p;
if (*p<min) min=*p;
// test.Printf(_L("%d\n"),*p);
test(IsPrime(*p));
}
test(c==aH.Count());
TInt x;
if (min==2)
{
test(aH.Find(2)!=0);
min++;
}
for (x=min; x<=max; x+=2)
{
if (IsPrime(x))
test(aH.Find(x)!=0);
}
for (x=min; x<=max; x+=2)
{
if (IsPrime(x))
test(aH.Find(x)==&aH.FindL(x));
else
{
TRAPD(rr,aH.FindL(x));
test(rr==KErrNotFound);
}
}
}
TUint32 CheckSmallHashSet(const TIntSet& aA)
{
TUint32 m = 0;
RHashSet<TInt>::TIter iter(aA);
FOREVER
{
const TInt* p = iter.Next();
if (!p)
break;
m |= (1<<*p);
}
return m;
}
void AddToSmallHashSet(TIntSet& aA, TUint32 aMask)
{
CheckSmallHashSet(aA);
TInt i;
TInt r;
for (i=0; i<32; ++i)
{
if (aMask & (1<<i))
{
r = aA.Insert(i);
test(r==KErrNone);
}
}
}
void RemoveFromSmallHashSet(TIntSet& aA, TUint32 aMask)
{
TUint32 m = CheckSmallHashSet(aA);
TInt i;
TInt r;
for (i=0; i<32; ++i)
{
if (aMask & (1<<i))
{
r = aA.Remove(i);
if (m & (1<<i))
test(r==KErrNone);
else
test(r==KErrNotFound);
}
}
}
void TestHashSet()
{
test.Next(_L("Test RHashSet"));
INTSET(hs);
CCheck(hs); // check consistency for empty table
INTSET(hs2);
INTSET(hs3);
PrimeSieve(hs, 1, 100);
CheckSieveOutput(hs);
test(hs.Reserve(1000)==KErrNone);
CCheck(hs);
CheckSieveOutput(hs); // check that Reserve() preserves existing entries
INTSET(m1);
INTSET(m2);
INTSET(m3);
INTSET(m5);
INTSET(m7);
Populate(m1,2,100,1);
Populate(m2,4,100,2);
Populate(m3,6,100,3);
Populate(m5,10,100,5);
Populate(m7,14,100,7);
Union(hs3, m1);
Subtract(hs3, m2);
Subtract(hs3, m3);
Subtract(hs3, m5);
Subtract(hs3, m7);
CheckSieveOutput(hs3);
CheckIdentical(hs,hs3);
hs3.Close();
INTSET(cm2);
INTSET(cm3);
INTSET(cm5);
INTSET(cm7);
Union(cm2, m1);
Subtract(cm2, m2);
Union(cm3, m1);
Subtract(cm3, m3);
Union(cm5, m1);
Subtract(cm5, m5);
Union(cm7, m1);
Subtract(cm7, m7);
Union(hs3, m1);
Intersect(hs3, cm7);
Intersect(hs3, cm3);
Intersect(hs3, cm5);
Intersect(hs3, cm2);
CheckSieveOutput(hs3);
CheckIdentical(hs,hs3);
hs3.Close();
cm2.Close();
cm3.Close();
cm5.Close();
cm7.Close();
m1.Close();
m2.Close();
m3.Close();
m5.Close();
m7.Close();
PrimeSieve(hs2, 1, 1000);
CheckSieveOutput(hs2);
test(hs2.Reserve(1000)==KErrNone);
CCheck(hs2);
CheckSieveOutput(hs2); // check that Reserve() preserves existing entries
PrimeSieve(hs, 100, 997);
CheckSieveOutput(hs);
CCheck(hs);
CheckIdentical(hs,hs2);
hs2.Close();
Union(hs2, hs);
CheckIdentical(hs,hs2);
CheckSieveOutput(hs2);
hs2.Close();
hs.Close();
test(CheckSmallHashSet(hs)==0);
AddToSmallHashSet(hs, 1);
test(CheckSmallHashSet(hs)==1);
AddToSmallHashSet(hs, 4);
test(CheckSmallHashSet(hs)==5);
AddToSmallHashSet(hs, 0x80000001);
test(CheckSmallHashSet(hs)==0x80000005);
AddToSmallHashSet(hs, 0x317217f8);
test(CheckSmallHashSet(hs)==0xb17217fd);
RemoveFromSmallHashSet(hs, 0x00000007);
test(CheckSmallHashSet(hs)==0xb17217f8);
RemoveFromSmallHashSet(hs, 0xffffffff);
test(CheckSmallHashSet(hs)==0);
hs.Close();
}
void TestHashIter()
{
test.Next(_L("Test iterators"));
RHashSet<TInt> hs; // empty
RHashSet<TInt>::TIter iter(hs);
test(iter.Next() == 0);
test(iter.Current() == 0);
iter.RemoveCurrent();
test(iter.Next() == 0);
test(iter.Current() == 0);
test(hs.Insert(1) == KErrNone);
test(hs.Insert(2) == KErrNone);
test(hs.Insert(3) == KErrNone);
iter.Reset();
TUint mask = 14;
TInt i;
for (i=0; i<3; ++i)
{
const TInt* p = iter.Next();
test(p!=0);
TInt x = *p;
test (x>=1 && x<=3 && (mask&(1<<x))!=0);
mask &= ~(1<<x);
}
test(iter.Next() == 0);
test(mask==0);
test(CheckSmallHashSet(hs)==0x0e);
test(hs.Insert(4) == KErrNone);
test(hs.Insert(5) == KErrNone);
test(hs.Insert(6) == KErrNone);
test(hs.Insert(7) == KErrNone);
test(CheckSmallHashSet(hs)==0xfe);
iter.Reset();
while(iter.Next())
{
if ((*iter.Current() & 1) == 0)
iter.RemoveCurrent();
}
test(CheckSmallHashSet(hs)==0xaa);
iter.Reset();
while(iter.Next())
{
iter.RemoveCurrent();
}
test(CheckSmallHashSet(hs)==0);
iter.Reset();
test(iter.Next() == 0);
test(iter.Current() == 0);
RHashSet<TInt> empty;
CheckIdentical(hs, empty);
#ifdef _DEBUG
__UHEAP_FAILNEXT(1);
test(empty.Insert(1)==KErrNoMemory);
test(empty.Insert(1)==KErrNone);
empty.Close();
__UHEAP_FAILNEXT(1);
test(hs.Insert(1)==KErrNone);
hs.Close();
__UHEAP_FAILNEXT(1);
test(hs.Insert(1)==KErrNoMemory);
#endif
hs.Close();
}
void Print(const char* aTitle, const RHashMap<TInt,TTestName>& aM)
{
TBuf<256> buf;
buf.Copy(TPtrC8((const TUint8*)aTitle));
test.Printf(_L("%S\n"), &buf);
RHashMap<TInt,TTestName>::TIter iter(aM);
FOREVER
{
const TInt* p = iter.NextKey();
if (!p) break;
buf.Copy(*iter.CurrentValue());
test.Printf(_L("%d: %S\n"), *p, &buf);
}
}
void Print(const char* aTitle, const RHashSet<TTestName>& aS)
{
TBuf<256> buf;
buf.Copy(TPtrC8((const TUint8*)aTitle));
test.Printf(_L("%S\n"), &buf);
RHashSet<TTestName>::TIter iter(aS);
FOREVER
{
if (!iter.Next())
break;
buf.Copy(*iter.Current());
test.Printf(_L("%S\n"), &buf);
}
}
void TestHashMap()
{
test.Next(_L("Test RHashMap"));
RHashMap<TInt,TInt> ht;
CCheck(ht); // check consistency for empty table
TInt x;
for (x=0; x<200; x++)
{
TInt r = ht.Insert(x*x, x);
test(r==KErrNone);
}
test(ht.Count()==200);
TInt z = 0;
TInt y;
for (x=0; x<40000; x++)
{
const TInt* e = ht.Find(x);
if (e)
{
const TInt& ee = ht.FindL(x);
test(&ee==e);
y = *e;
// test.Printf(_L("Find(%d) -> %d\n"), x, y);
test(x == z*z);
test(y == z);
++z;
}
else
{
TRAPD(rr, ht.FindL(x));
test(rr==KErrNotFound);
}
}
CCheck(ht);
for (x=0; x<200; x++)
{
TInt r = ht.Insert(x*x*x, x);
test(r==KErrNone);
}
test(ht.Count()==200*2-6);
CCheck(ht);
TInt sq = 0;
TInt cb = 0;
for (x=0; x<8000000; x++)
{
const TInt* e = ht.Find(x);
if (e)
{
const TInt& ee = ht.FindL(x);
test(&ee==e);
y = *e;
// test.Printf(_L("Find(%d) -> %d\n"), x, y);
if (x == cb*cb*cb)
{
test(y==cb);
++cb;
if (x == sq*sq)
++sq;
}
else if (x == sq*sq)
{
test(y==sq);
++sq;
}
}
}
for (x=0; x<200; x++)
{
TInt r = ht.Remove(x*x);
test(r==KErrNone);
}
test(ht.Count()==200-6);
CCheck(ht);
cb = 2;
for (x=2; x<8000000; x++)
{
const TInt* e = ht.Find(x);
if (e)
{
const TInt& ee = ht.FindL(x);
test(&ee==e);
y = *e;
// test.Printf(_L("Find(%d) -> %d\n"), x, y);
if (cb == 4 || cb == 9 || cb == 16 || cb == 25) ++cb;
test(x == cb*cb*cb);
test(y == cb);
++cb;
}
}
SetMap<TInt,TInt>(ht, 17);
ht.Close();
PrintNumberInWords(2000);
PrintNumberInWords(2001);
PrintNumberInWords(131072);
PrintNumberInWords(111111);
PrintNumberInWords(524288);
INTSET(all);
Populate(all,0,1000,1);
RHashMap<TInt,TTestName> to_words(&DefaultHash::Integer, &DefaultIdentity::Integer);
UnionTransform<TInt,TTestName>(to_words, all, &NumberInWords);
RHashMap<TTestName,TInt> from_words(&HashTestName, &TestNameIdentity);
UnionInverse<TInt,TTestName>(from_words, to_words);
// Print("TO WORDS:", to_words);
INTSET(primes);
PrimeSieve(primes, 1, 100);
// Print("Primes 1-100", primes);
RHashMap<TInt,TTestName> prime_map(&DefaultHash::Integer, &DefaultIdentity::Integer);
UnionTransform<TInt,TTestName>(prime_map, primes, &NumberInWords);
// Print("Prime map 1-100", prime_map);
INTSET(pmkeys);
UnionKeys<TInt,TTestName>(pmkeys, prime_map);
NAMESET(pmval);
NAMESET(pmval2);
UnionValues<TInt,TTestName>(pmval, prime_map);
CheckIdentical(pmkeys, primes);
INTSET(pr2);
UnionMap<TTestName,TInt>(pr2, pmval, from_words);
CheckIdentical(pr2, primes);
pr2.Close();
Union(pmval2, pmval);
// Print("pmval",pmval);
// Print("pmval2",pmval2);
CheckIdentical(pmval2, pmval);
UnionMap<TTestName,TInt>(pr2, pmval2, from_words);
CheckIdentical(pr2, primes);
pr2.Close();
pmval.Close();
pmval2.Close();
pmkeys.Close();
prime_map.Close();
primes.Close();
all.Close();
INTSET(m);
Populate(all,2,1000,1);
NAMESET(pr3);
NAMESET(nm);
UnionMap<TInt,TTestName>(pr3, all, to_words);
all.Close();
CCheck(pr3);
Populate(m,4,1000,2);
UnionMap<TInt,TTestName>(nm, m, to_words);
m.Close();
Subtract(pr3, nm);
nm.Close();
Populate(m,6,1000,3);
UnionMap<TInt,TTestName>(nm, m, to_words);
m.Close();
Subtract(pr3, nm);
nm.Close();
Populate(m,10,1000,5);
UnionMap<TInt,TTestName>(nm, m, to_words);
m.Close();
Subtract(pr3, nm);
nm.Close();
Populate(m,14,1000,7);
UnionMap<TInt,TTestName>(nm, m, to_words);
m.Close();
Subtract(pr3, nm);
nm.Close();
Populate(m,22,1000,11);
UnionMap<TInt,TTestName>(nm, m, to_words);
m.Close();
Subtract(pr3, nm);
nm.Close();
Populate(m,26,1000,13);
UnionMap<TInt,TTestName>(nm, m, to_words);
m.Close();
Subtract(pr3, nm);
nm.Close();
Populate(m,34,1000,17);
UnionMap<TInt,TTestName>(nm, m, to_words);
m.Close();
Subtract(pr3, nm);
nm.Close();
Populate(m,38,1000,19);
UnionMap<TInt,TTestName>(nm, m, to_words);
m.Close();
Subtract(pr3, nm);
nm.Close();
Populate(m,46,1000,23);
UnionMap<TInt,TTestName>(nm, m, to_words);
m.Close();
Subtract(pr3, nm);
nm.Close();
Populate(m,58,1000,29);
UnionMap<TInt,TTestName>(nm, m, to_words);
m.Close();
Subtract(pr3, nm);
nm.Close();
Populate(m,62,1000,31);
UnionMap<TInt,TTestName>(nm, m, to_words);
m.Close();
Subtract(pr3, nm);
nm.Close();
// Print("pr3",pr3);
PrimeSieve(primes, 1, 1000);
UnionMap<TInt,TTestName>(nm, primes, to_words);
CheckIdentical(nm, pr3);
CCheck(pr3);
UnionMap<TTestName,TInt>(m, pr3, from_words);
CheckIdentical(m, primes);
m.Close();
nm.Close();
primes.Close();
pr3.Close();
from_words.Close();
to_words.Close();
}
void PopulateArray8(TInt aMax)
{
TInt i;
for (i=0; i<aMax; ++i)
{
TTestName n(NumberInWords(i));
HBufC8* p = n.Alloc();
test(p!=0);
TInt r = DesC8Array.Append(p);
test(r==KErrNone);
}
}
void PopulateArray16(TInt aMax)
{
TInt i;
for (i=0; i<aMax; ++i)
{
TTestName n(NumberInWords(i));
TBuf<128> n16;
n16.Copy(n);
HBufC16* p = n16.Alloc();
test(p!=0);
TInt r = DesC16Array.Append(p);
test(r==KErrNone);
}
}
TUint32 istrh8(const TDesC8* const & a)
{
return DefaultHash::Des8(*a);
}
TBool istrid8(const TDesC8* const & aA, const TDesC8* const & aB)
{
return *aA == *aB;
}
TUint32 istrh16(const TDesC16* const & a)
{
return DefaultHash::Des16(*a);
}
TBool istrid16(const TDesC16* const & aA, const TDesC16* const & aB)
{
return *aA == *aB;
}
void TestPtrHashSet()
{
test.Next(_L("Test RPtrHashSet"));
STRSET8(s);
CCheck(s); // check consistency for empty table
RHashMap<const TDesC8*, TInt> hm(&istrh8, &istrid8);
RPtrHashSet<TDesC8>::TIter iter(s);
const TDesC8* q;
TInt i;
for (i=0; i<4096; ++i)
{
TInt r = s.Insert(DesC8Array[i]);
test(r==KErrNone);
r = hm.Insert(DesC8Array[i], i);
test(r==KErrNone);
}
CCheck(s);
for (i=0; i<4100; ++i)
{
TTestName n(NumberInWords(i));
const TDesC8* p = s.Find(n);
if (i<4096)
{
const TDesC8& pp = s.FindL(n);
test(p && *p==n && p==DesC8Array[i]);
test(&pp == p);
}
else
{
test(!p);
TRAPD(rr,s.FindL(n));
test(rr==KErrNotFound);
}
}
while((q=iter.Next())!=0)
{
const TInt* qi = hm.Find(q);
test(qi!=0 && *qi>=0 && *qi<4096);
test(DesC8Array[*qi]==q);
}
for (i=0; i<4100; i+=2)
{
TTestName n(NumberInWords(i));
TInt r = s.Remove(&n);
if (i<4096)
test(r==KErrNone);
else
test(r==KErrNotFound);
}
test(s.Count()==2048);
CCheck(s);
for (i=0; i<4100; ++i)
{
TTestName n(NumberInWords(i));
const TDesC8* p = s.Find(n);
if (i<4096 && (i&1))
test(p && *p==n && p==DesC8Array[i]);
else
test(!p);
}
iter.Reset();
while((q=iter.Next())!=0)
{
const TInt* qi = hm.Find(q);
test(qi!=0 && *qi>=0 && *qi<4096 && (*qi&1));
test(DesC8Array[*qi]==q);
}
for (i=2; i<4096; i+=4)
{
TInt r = s.Insert(DesC8Array[i]);
test(r==KErrNone);
}
test(s.Count()==3072);
CCheck(s);
for (i=0; i<4100; ++i)
{
TTestName n(NumberInWords(i));
const TDesC8* p = s.Find(n);
if (i<4096 && (i&3))
test(p && *p==n && p==DesC8Array[i]);
else
test(!p);
}
iter.Reset();
while((q=iter.Next())!=0)
{
const TInt* qi = hm.Find(q);
test(qi!=0 && *qi>=0 && *qi<4096 && (*qi&3));
test(DesC8Array[*qi]==q);
}
s.Close();
// test ResetAndDestroy
for (i=0; i<16; ++i)
{
TInt r = s.Insert(DesC8Array[i]->Alloc());
test(r==KErrNone);
}
iter.Reset();
while((q=iter.Next())!=0)
{
const TInt* qi = hm.Find(q);
test(qi!=0 && *qi>=0 && *qi<16);
test(*DesC8Array[*qi]==*q);
test(DesC8Array[*qi]!=q);
}
s.ResetAndDestroy();
hm.Close();
STRSET16(S);
RHashMap<const TDesC16*, TInt> HM(&istrh16, &istrid16);
RPtrHashSet<TDesC16>::TIter ITER(S);
const TDesC16* Q;
for (i=0; i<4096; ++i)
{
TInt r = S.Insert(DesC16Array[i]);
test(r==KErrNone);
r = HM.Insert(DesC16Array[i], i);
test(r==KErrNone);
}
CCheck(S);
for (i=0; i<4100; ++i)
{
TTestName n(NumberInWords(i));
TBuf<80> buf;
buf.Copy(n);
const TDesC16* p = S.Find(buf);
if (i<4096)
test(p && *p==buf && p==DesC16Array[i]);
else
test(!p);
}
while((Q=ITER.Next())!=0)
{
const TInt* qi = HM.Find(Q);
test(qi!=0 && *qi>=0 && *qi<4096);
test(DesC16Array[*qi]==Q);
}
for (i=0; i<4100; i+=2)
{
TTestName n(NumberInWords(i));
TBuf<80> buf;
buf.Copy(n);
TInt r = S.Remove(&buf);
if (i<4096)
test(r==KErrNone);
else
test(r==KErrNotFound);
}
test(S.Count()==2048);
CCheck(S);
for (i=0; i<4100; ++i)
{
TTestName n(NumberInWords(i));
TBuf<80> buf;
buf.Copy(n);
const TDesC16* p = S.Find(buf);
if (i<4096 && (i&1))
test(p && *p==buf && p==DesC16Array[i]);
else
test(!p);
}
ITER.Reset();
while((Q=ITER.Next())!=0)
{
const TInt* qi = HM.Find(Q);
test(qi!=0 && *qi>=0 && *qi<4096 && (*qi&1));
test(DesC16Array[*qi]==Q);
}
for (i=2; i<4096; i+=4)
{
TInt r = S.Insert(DesC16Array[i]);
test(r==KErrNone);
}
test(S.Count()==3072);
CCheck(S);
for (i=0; i<4100; ++i)
{
TTestName n(NumberInWords(i));
TBuf<80> buf;
buf.Copy(n);
const TDesC16* p = S.Find(buf);
if (i<4096 && (i&3))
test(p && *p==buf && p==DesC16Array[i]);
else
test(!p);
}
ITER.Reset();
while((Q=ITER.Next())!=0)
{
const TInt* qi = HM.Find(Q);
test(qi!=0 && *qi>=0 && *qi<4096 && (*qi&3));
test(DesC16Array[*qi]==Q);
}
S.Close();
// test ResetAndDestroy
for (i=0; i<16; ++i)
{
TInt r = S.Insert(DesC16Array[i]->Alloc());
test(r==KErrNone);
}
ITER.Reset();
while((Q=ITER.Next())!=0)
{
const TInt* qi = HM.Find(Q);
test(qi!=0 && *qi>=0 && *qi<16);
test(*DesC16Array[*qi]==*Q);
test(DesC16Array[*qi]!=Q);
}
S.ResetAndDestroy();
HM.Close();
}
void TestPtrHashMap()
{
test.Next(_L("Test RPtrHashMap"));
STRMAP8(map);
CCheck(map); // check consistency for empty table
STRMAP8(id);
TInt i;
for (i=0; i<4096; ++i)
{
TInt r = map.Insert(DesC8Array[i], DesC8Array[(i+1)&0xfff]);
test(r==KErrNone);
r = id.Insert(DesC8Array[i], DesC8Array[i]);
test(r==KErrNone);
}
for (i=0; i<4096; ++i)
{
const TDesC8* p = map.Find(*DesC8Array[i]);
test(p == DesC8Array[(i+1)&0xfff]);
const TDesC8& pp = map.FindL(*DesC8Array[i]);
test(&pp == p);
}
TRAPD(rr,map.FindL(_L8("two")));
test(rr==KErrNone);
TRAP(rr,map.FindL(_L8("twx")));
test(rr==KErrNotFound);
CCheck(map);
STRMAP8(map2);
STRMAP8(mapi);
STRMAP8(map3);
UnionInverse<TDesC8,TDesC8>(mapi, map);
UnionCompose<TDesC8,TDesC8,TDesC8>(map2, map, map);
UnionCompose<TDesC8,TDesC8,TDesC8>(map3, map, mapi);
CheckIdenticalMaps<TDesC8,TDesC8>(map3, id);
map3.Close();
UnionCompose<TDesC8,TDesC8,TDesC8>(map3, map2, mapi);
CheckIdenticalMaps<TDesC8,TDesC8>(map3, map);
map3.Close();
for (i=0; i<4096; ++i)
{
TInt r = map3.Insert(DesC8Array[i], DesC8Array[(i+2)&0xfff]);
test(r==KErrNone);
}
CheckIdenticalMaps<TDesC8,TDesC8>(map3, map2);
map3.Close();
mapi.Close();
map2.Close();
id.Close();
map.Close();
// test ResetAndDestroy()
for(i=0; i<16; ++i)
{
TInt r = map.Insert(DesC8Array[i]->Alloc(), DesC8Array[i*i]->Alloc());
test(r==KErrNone);
}
map.ResetAndDestroy();
}
void TestOOM()
{
// Max out memory and check it still works
test.Next(_L("Test OOM"));
TInt x = 0;
TInt n = 0;
TInt r;
INTSET(set);
FOREVER
{
x += 0x58b90bfb;
r = set.Insert(x);
if (r != KErrNone)
break;
++n;
}
test(r==KErrNoMemory);
TRAPD(rr,set.InsertL(x));
test(rr==KErrNoMemory);
test.Printf(_L("%d integers stored\n"), n);
test(set.Count()==n);
TRAP(rr,set.InsertL(0x58b90bfb)); // already there
test(rr==KErrNone); // should succeed
// final count should be a power of 2 minus 1
test( (n&(n+1)) == 0 );
x = 0;
TInt i;
for (i=0; i<=n; ++i) // check everything has been stored correctly
{
x += 0x58b90bfb;
const TInt* p = set.Find(x);
if (i < n)
test(p && *p == x);
else
test(!p);
}
set.Close();
TInt nn;
for (nn=256; nn<=n+256; nn+=256)
{
r = set.Reserve(nn);
set.Close();
if (r!=KErrNone)
break;
}
test.Printf(_L("Max reserve %d\n"),nn);
TInt thresh = 3*((n+1)>>2);
test(nn == thresh + 256);
}
class RDummyAllocator : public RAllocator
{
public:
virtual TAny* Alloc(TInt) {test(0); return 0;}
virtual void Free(TAny*) {test(0);}
virtual TAny* ReAlloc(TAny*, TInt, TInt) {test(0); return 0;}
virtual TInt AllocLen(const TAny*) const {test(0); return 0;}
virtual TInt Compress() {test(0); return 0;}
virtual void Reset() {test(0);}
virtual TInt AllocSize(TInt&) const {test(0); return 0;}
virtual TInt Available(TInt&) const {test(0); return 0;}
virtual TInt DebugFunction(TInt, TAny*, TAny*) {test(0); return 0;}
virtual TInt Extension_(TUint, TAny*&, TAny*) {test(0); return 0;}
};
void IntegerBenchmark(TInt aCount, TBool aReserve)
{
RArray<TInt> array;
TUint32 before, after, diff;
TInt x=0;
TInt i;
double avg;
test.Printf(_L("**** INTEGER BENCHMARKS ***\n"));
if (!aReserve)
{
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x += 0x58b90bfb;
TInt r = array.InsertInOrder(x);
test(r==KErrNone);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d insertions take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x += 0x58b90bfb;
TInt r = array.FindInOrder(x);
test(r>=0);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d successful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x += 0x58b90bfb;
TInt r = array.FindInOrder(x);
test(r==KErrNotFound);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d unsuccessful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x += 0x58b90bfb;
TInt r = array.FindInOrder(x);
test(r>=0);
array.Remove(r);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d deletions take %dus (%.2gus each)\n"), aCount, diff, avg);
array.Close();
}
INTSET(set);
x=0;
RAllocator* pA = 0;
RDummyAllocator da;
if (aReserve)
{
test(set.Reserve(aCount)==KErrNone);
pA = User::SwitchAllocator(&da); // check that no memory accesses occur
test(set.Reserve(10)==KErrNone); // shouldn't need to do anything
test(set.Reserve(aCount/2)==KErrNone); // shouldn't need to do anything
test(set.Reserve(aCount)==KErrNone); // shouldn't need to do anything
}
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x += 0x58b90bfb;
TInt r = set.Insert(x); // we have no heap here so this tests that Reserve() has preallocated sufficient memory
test(r==KErrNone);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
if (aReserve)
User::SwitchAllocator(pA);
test.Printf(_L("HASH TABLE: %d insertions take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x += 0x58b90bfb;
const TInt* p = set.Find(x);
test(p!=0);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("HASH TABLE: %d successful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x += 0x58b90bfb;
const TInt* p = set.Find(x);
test(!p);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("HASH TABLE: %d unsuccessful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x += 0x58b90bfb;
TInt r = set.Remove(x);
test(r==KErrNone);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("HASH TABLE: %d deletions take %dus (%.2gus each)\n"), aCount, diff, avg);
set.Close();
}
TInt des8order(const TDesC8& aA, const TDesC8& aB)
{
return aA.Compare(aB);
}
void StringBenchmark8(TInt aCount, TBool aReserve)
{
RPointerArray<TDesC8> array;
TUint32 before, after, diff;
TInt x=0;
TInt i;
double avg;
const TDesC8** base = (const TDesC8**)&DesC8Array[0];
test(base[1331] == DesC8Array[1331]);
test.Printf(_L("**** 8 BIT STRING BENCHMARKS ***\n"));
if (!aReserve)
{
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = array.InsertInOrder(base[x], &des8order);
test(r==KErrNone);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d insertions take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = array.FindInOrder(base[x], &des8order);
test(r>=0);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d successful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = array.FindInOrder(base[x], &des8order);
test(r==KErrNotFound);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d unsuccessful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = array.FindInOrder(base[x], &des8order);
test(r>=0);
array.Remove(r);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d deletions take %dus (%.2gus each)\n"), aCount, diff, avg);
array.Close();
}
STRSET8(set);
x=0;
if (aReserve)
test(set.Reserve(aCount)==KErrNone);
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = set.Insert(base[x]);
test(r==KErrNone);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("HASH TABLE: %d insertions take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
const TDesC8* p = set.Find(*base[x]);
test(p!=0);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("HASH TABLE: %d successful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
const TDesC8* p = set.Find(*base[x]);
test(!p);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("HASH TABLE: %d unsuccessful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = set.Remove(base[x]);
test(r==KErrNone);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("HASH TABLE: %d deletions take %dus (%.2gus each)\n"), aCount, diff, avg);
set.Close();
}
TInt des16order(const TDesC16& aA, const TDesC16& aB)
{
return aA.Compare(aB);
}
void StringBenchmark16(TInt aCount, TBool aReserve)
{
RPointerArray<TDesC16> array;
TUint32 before, after, diff;
TInt x=0;
TInt i;
double avg;
const TDesC16** base = (const TDesC16**)&DesC16Array[0];
test(base[1331] == DesC16Array[1331]);
test.Printf(_L("**** 16 BIT STRING BENCHMARKS ***\n"));
if (!aReserve)
{
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = array.InsertInOrder(base[x], &des16order);
test(r==KErrNone);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d insertions take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = array.FindInOrder(base[x], &des16order);
test(r>=0);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d successful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = array.FindInOrder(base[x], &des16order);
test(r==KErrNotFound);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d unsuccessful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = array.FindInOrder(base[x], &des16order);
test(r>=0);
array.Remove(r);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("ARRAY: %d deletions take %dus (%.2gus each)\n"), aCount, diff, avg);
array.Close();
}
STRSET16(set);
x=0;
if (aReserve)
test(set.Reserve(aCount)==KErrNone);
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = set.Insert(base[x]);
test(r==KErrNone);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("HASH TABLE: %d insertions take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
const TDesC16* p = set.Find(*base[x]);
test(p!=0);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("HASH TABLE: %d successful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
const TDesC16* p = set.Find(*base[x]);
test(!p);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("HASH TABLE: %d unsuccessful finds take %dus (%.2gus each)\n"), aCount, diff, avg);
x=0;
before = User::NTickCount();
for (i=0; i<aCount; ++i)
{
x = (x+4339)&0x3fff;
TInt r = set.Remove(base[x]);
test(r==KErrNone);
}
after = User::NTickCount();
diff = after - before;
diff *= NanoTickPeriod;
avg = (double)diff / (double)aCount;
test.Printf(_L("HASH TABLE: %d deletions take %dus (%.2gus each)\n"), aCount, diff, avg);
set.Close();
}
void Benchmark()
{
test.Next(_L("Benchmarks ..."));
IntegerBenchmark(1000, EFalse);
IntegerBenchmark(1000, ETrue);
IntegerBenchmark(2000, EFalse);
IntegerBenchmark(2000, ETrue);
IntegerBenchmark(4000, EFalse);
IntegerBenchmark(4000, ETrue);
IntegerBenchmark(8000, EFalse);
IntegerBenchmark(8000, ETrue);
IntegerBenchmark(16000, EFalse);
IntegerBenchmark(16000, ETrue);
IntegerBenchmark(32000, EFalse);
IntegerBenchmark(32000, ETrue);
PopulateArray8(16384);
StringBenchmark8(1000, EFalse);
StringBenchmark8(2000, EFalse);
StringBenchmark8(4000, EFalse);
StringBenchmark8(8000, EFalse);
DesC8Array.ResetAndDestroy();
PopulateArray16(16384);
StringBenchmark16(1000, EFalse);
StringBenchmark16(2000, EFalse);
StringBenchmark16(4000, EFalse);
StringBenchmark16(8000, EFalse);
DesC16Array.ResetAndDestroy();
}
TUint32 mp(TUint32 x)
{
TUint32 x3 = x+(x<<1);
TUint32 x7 = x+(x3<<1);
TUint32 x15 = x+(x7<<1);
TUint32 y = x + (x7<<3) + (x3<<7) + (x15<<11) + (x7<<16) + (x3<<20) + (x15<<25) + (x<<31);
return y;
}
TUint32 strh(const char* aIn)
{
TUint32 h = 0;
TInt i = 0;
while (*aIn)
{
if (i==0)
h = mp(h);
TUint32 c = *aIn++;
c <<= (8*i);
h ^= c;
i = (i+1)&3;
}
return mp(h);
}
TUint32 strh(const wch* aIn)
{
TUint32 h = 0;
TInt i = 0;
while (*aIn)
{
if (i==0)
h = mp(h);
TUint32 c = *aIn++;
switch (i)
{
case 0: break;
case 1: c<<=16; break;
case 2: c<<=8; break;
default: c=(c<<24)|(c>>8); break;
};
h ^= c;
i = (i+1)&3;
}
return mp(h);
}
void TestHash(TInt* aIn, TUint32 aExpected)
{
THashFunction32<TInt*> hf(&DefaultHash::IntegerPtr);
TUint32 out = hf.Hash(aIn);
test(aExpected == mp((TUint32)aIn));
if (out != aExpected)
{
test.Printf(_L("Hashing %08x Expected %08x Got %08x\n"), aIn, aExpected, out);
test(0);
}
}
void TestHash(TDesC8* aIn, TUint32 aExpected)
{
THashFunction32<TDesC8*> hf(&DefaultHash::Des8Ptr);
TUint32 out = hf.Hash(aIn);
test(aExpected == mp((TUint32)aIn));
if (out != aExpected)
{
test.Printf(_L("Hashing %08x Expected %08x Got %08x\n"), aIn, aExpected, out);
test(0);
}
}
void TestHash(TDesC16* aIn, TUint32 aExpected)
{
THashFunction32<TDesC16*> hf(&DefaultHash::Des16Ptr);
TUint32 out = hf.Hash(aIn);
test(aExpected == mp((TUint32)aIn));
if (out != aExpected)
{
test.Printf(_L("Hashing %08x Expected %08x Got %08x\n"), aIn, aExpected, out);
test(0);
}
}
void TestHash(TInt aIn, TUint32 aExpected)
{
THashFunction32<TInt> hf(&DefaultHash::Integer);
TUint32 out = hf.Hash(aIn);
test(aExpected == mp((TUint32)aIn));
if (out != aExpected)
{
test.Printf(_L("Hashing %08x Expected %08x Got %08x\n"), aIn, aExpected, out);
test(0);
}
}
void TestHash(const char* aIn, TUint32 aExpected)
{
THashFunction32<TDesC8> hf(&DefaultHash::Des8);
TPtrC8 p((const TUint8*)aIn);
TUint32 out = hf.Hash(p);
test(aExpected == strh(aIn));
if (out != aExpected)
{
TBuf<256> buf;
buf.Copy(p);
test.Printf(_L("Hashing %S (len %d) Expected %08x Got %08x\n"), &buf, p.Length(), aExpected, out);
test(0);
}
}
void TestHash(const wch* aIn)
{
THashFunction32<TDesC16> hf(&DefaultHash::Des16);
TPtrC16 p((const TUint16*)aIn);
TUint32 out = hf.Hash(p);
TUint32 exp = strh(aIn);
if (out != exp)
{
test.Printf(_L("Hashing %S (len %d) Expected %08x Got %08x\n"), &p, p.Size(), exp, out);
test(0);
}
}
void TestHash()
{
test.Next(_L("Test integer hash"));
TestHash(1,0x9e3779b9);
TestHash(2,0x3c6ef372);
TestHash(4,0x78dde6e4);
TestHash(8,0xf1bbcdc8);
TestHash(16,0xe3779b90);
TestHash(0xc90fdaa2,0xbf999112);
TestHash(0xb504f334,0x7fb35494);
TestHash(0xddb3d743,0xd11a3a6b);
TestHash(0xadf85458,0x873a8b98);
TestHash(0x11730859,0xb4321951);
TestHash(0x64636261,0x8628f119);
}
void TestIntegerPtrHash()
{
TInt i[5];
TInt* ptr;
test.Next(_L("Test Integer pointer hash"));
for (ptr=i; ptr<i+5; ptr++)
{
TestHash(ptr, DefaultHash::IntegerPtr(ptr));
}
}
void TestDes8PtrHash()
{
TBuf8<8> i[5];
TDesC8* ptr;
test.Next(_L("Test Des8 pointer hash"));
for (ptr=i; ptr<i+5; ptr++)
{
TestHash(ptr, DefaultHash::Des8Ptr(ptr));
}
}
void TestDes16PtrHash()
{
TBuf16<8> i[5];
TDesC16* ptr;
test.Next(_L("Test Des16 pointer hash"));
for (ptr=i; ptr<i+5; ptr++)
{
TestHash(ptr, DefaultHash::Des16Ptr(ptr));
}
}
const char teststr[] = "zyxwvutsrq";
void TestStringHash()
{
test.Next(_L("Test 8 bit string hash"));
TestHash("",0x0);
TestHash("a",0xf3051f19);
TestHash("b",0x913c98d2);
TestHash("ab",0x2f9df119);
TestHash("ba",0x965bb1d2);
TestHash("abc",0x4228f119);
TestHash("abcd",0x8628f119);
TestHash("abcde",0xb75e1e9c);
TestHash("abcdef",0x3693149c);
TestHash("abcdefg",0xc1c2149c);
TestHash("abcdefgh",0xe9c2149c);
TestHash("abcdefghi",0x5fcbf20d);
TestHash("abcdefghj",0xfe036bc6);
TestHash(teststr, 0x108ca51e);
TestHash(teststr+1, 0x551002ad);
TestHash(teststr+2, 0x37dc0d6c);
TestHash(teststr+3, 0x2937f92c);
TestHash(teststr+4, 0xf0818a94);
TestHash(teststr+5, 0xb1b25f1c);
TestHash(teststr+6, 0x7a3342d4);
TestHash(teststr+7, 0x81c9101b);
TestHash(teststr+8, 0xf16edd62);
TestHash(teststr+9, 0xd67cbaa9);
TestHash(teststr+10, 0);
char t[16];
int i,j;
for (i=0; i<=4; ++i)
{
for (j=0; j<=10; ++j)
{
const char* s = teststr + j;
int l = User::StringLength((const TUint8*)s);
memset(t, 0xbb, 16);
memcpy(t+i, s, l+1);
TUint32 h;
switch (j)
{
case 0: h = 0x108ca51e; break;
case 1: h = 0x551002ad; break;
case 2: h = 0x37dc0d6c; break;
case 3: h = 0x2937f92c; break;
case 4: h = 0xf0818a94; break;
case 5: h = 0xb1b25f1c; break;
case 6: h = 0x7a3342d4; break;
case 7: h = 0x81c9101b; break;
case 8: h = 0xf16edd62; break;
case 9: h = 0xd67cbaa9; break;
default: h = 0; break;
};
TestHash(t+i, h);
}
}
}
const wch wteststr[] = L"zyxwvutsrq";
void TestWStringHash()
{
test.Next(_L("Test 16 bit string hash"));
TestHash(L"");
TestHash(L"a");
TestHash(L"b");
TestHash(L"ab");
TestHash(L"ba");
TestHash(L"abc");
TestHash(L"abcd");
TestHash(L"abcde");
TestHash(L"abcdef");
TestHash(L"abcdefg");
TestHash(L"abcdefgh");
TestHash(L"abcdefghi");
TestHash(L"abcdefghj");
TestHash(wteststr);
TestHash(wteststr+1);
TestHash(wteststr+2);
TestHash(wteststr+3);
TestHash(wteststr+4);
TestHash(wteststr+5);
TestHash(wteststr+6);
TestHash(wteststr+7);
TestHash(wteststr+8);
TestHash(wteststr+9);
TestHash(wteststr+10);
wch t[16];
int i,j;
for (i=0; i<=4; ++i)
{
for (j=0; j<=10; ++j)
{
const wch* s = wteststr + j;
int l = User::StringLength((const TUint16*)s);
memset(t, 0xbb, 2*16);
memcpy(t+i, s, 2*(l+1));
TestHash(t+i);
}
}
}
template <class K,class V>
void TestHashMapPtr(RHashMap<K,V> &map, K ptr, V* i)
{
test(map.Reserve(5) == KErrNone);
for (ptr=i;ptr<i+5;ptr++)
{
test(map.Insert(ptr,*ptr) == KErrNone);
}
for (ptr=i+4;ptr>=i;ptr--)
{
test(*(map.Find(ptr)) == *ptr);
}
test(map.Count() == 5);
test(map.Remove(i) == KErrNone);
test(map.Count()==4);
test(map.Find(i)==NULL);
map.Close();
}
void TestPtrHashMaps()
{
test.Next(_L("Test RHashMap of default pointer types"));
TInt i[5];
TInt *ptr=i;
RHashMap<TInt*,TInt> mp;
TestHashMapPtr(mp, ptr, i);
TInt32 i1[5];
TInt32 *ptr1=i1;
RHashMap<TInt32*,TInt32> mp1;
TestHashMapPtr(mp1,ptr1,i1);
TUint i2[5];
TUint *ptr2=i2;
RHashMap<TUint*,TUint> mp2;
TestHashMapPtr(mp2,ptr2,i2);
TUint32 i3[5];
TUint32 *ptr3=i3;
RHashMap<TUint32*,TUint32> mp3;
TestHashMapPtr(mp3,ptr3,i3);
TBuf8<5> i4[5];
TBuf8<5> *ptr4=i4;
RHashMap<TDesC8*,TDesC8> mp4;
for (ptr4=i4; ptr4 < i4+5; ptr4++)
{
test(mp4.Insert(ptr4,*ptr4) == KErrNone);
}
for (ptr4=i4+4; ptr4 >= i4; ptr4--)
{
test(*(mp4.Find(ptr4)) == *ptr4);
}
test(mp4.Count()==5);
test(mp4.Remove(i4) == KErrNone);
test(mp4.Find(i4) == NULL);
test(mp4.Count()==4);
mp4.Close();
TBuf16<5> i5[5];
TBuf16<5> *ptr5=i5;
RHashMap<TDesC16*,TDesC16> mp5;
for (ptr5=i5; ptr5 < i5+5; ptr5++)
{
test(mp5.Insert(ptr5,*ptr5) == KErrNone);
}
for (ptr5=i5+4; ptr5 >= i5; ptr5--)
{
test(*(mp5.Find(ptr5)) == *ptr5);
}
test(mp5.Count()==5);
test(mp5.Remove(i5) == KErrNone);
test(mp5.Find(i5) == NULL);
test(mp5.Count()==4);
mp5.Close();
}
/** Tests that Reserve() will always allocate memory for new tables
even for small reserve sizes
See DEF087906.
*/
void TestSmallReserve()
{
test.Next(_L("Test RHashTableBase::Reserve preallocates memory, even for small no of elements"));
RAllocator* pA = 0;
RDummyAllocator da;
// Reserve should allocate the memory required for the table of 1 element
INTSET(set);
RHashMap<TInt,TInt> hashMap;
test(set.Reserve(1) == KErrNone);
test(hashMap.Reserve(1) == KErrNone);
pA = User::SwitchAllocator(&da);
// No more memory should be allocated for the table as it should
// have been already allocated by Reserve()
test(set.Insert(123) == KErrNone);
test(hashMap.Insert(123,456) == KErrNone);
// Switch back to allow set to be closed
User::SwitchAllocator(pA);
set.Close();
hashMap.Close();
}
TInt E32Main()
{
test.Title();
test(HAL::Get(HAL::ENanoTickPeriod, NanoTickPeriod)==KErrNone);
test.Printf(_L("NanoTickPeriod %dus\n"), NanoTickPeriod);
__UHEAP_MARK;
test.Start(_L("Testing hash tables"));
TestHash();
TestStringHash();
TestWStringHash();
TestIntegerPtrHash();
TestDes8PtrHash();
TestDes16PtrHash();
TestHashSet();
TestHashIter();
TestHashMap();
TestPtrHashMaps();
PopulateArray8(4096);
PopulateArray16(4096);
TestPtrHashSet();
TestPtrHashMap();
DesC16Array.ResetAndDestroy();
DesC8Array.ResetAndDestroy();
TestOOM();
Benchmark();
TestSmallReserve();
test.End();
__UHEAP_MARKEND;
return 0;
}