Update Windows installation script to put Python 2.6.4 into the Windows installer.
/*
* Copyright (c) 1997-2009 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:
*
*/
#include <assert.h>
#include <string.h>
#include <ctype.h>
#include <stdlib.h>
#if defined(__MSVCDOTNET__) || defined(__TOOLS2__)
#include <sstream>
#include <iostream>
using std::cerr;
using std::endl;
#else //!__MSVCDOTNET__
#ifndef __LINUX__
#include <strstrea.h>
#endif //!__LINUX__
#endif //__MSVCDOTNET__
#include "ASTRING.H"
#include "NUMVAL.H"
#include "STRUCTST.H"
#include "Parser.h"
#include "rcomp.hpp"
#include "MEM.H"
#include "ERRORHAN.H"
#include "RCBINSTR.H"
#if defined(__VC32__)
#pragma warning( disable : 4702 ) // unreachable code
#endif
NumericValue::NumericValue( const String & Source, DataType NumericValueType):
iNumericValueType( NumericValueType),
iData( NULL),
iULongValue( 0),
iSignedValue( 0),
iDoubleValue( 0.0)
{
AllocateSpace();
ConvertToNumber( Source);
}
NumericValue::NumericValue( DataType NumericValueType):
iNumericValueType( NumericValueType),
iData( NULL),
iULongValue( 0),
iSignedValue( 0),
iDoubleValue( 0.0)
{
AllocateSpace();
}
NumericValue::NumericValue( unsigned long ValueToSet, DataType NumericValueType):
iNumericValueType( NumericValueType),
iData( NULL),
iULongValue( 0),
iSignedValue( 0),
iDoubleValue( 0.0)
{
AllocateSpace();
StoreValue( ValueToSet);
}
NumericValue::~NumericValue()
{
delete [] iData;
}
NumericValue::NumericValue( const NumericValue & Source):
iNumericValueType( Source.iNumericValueType),
iData( NULL),
iULongValue( 0),
iSignedValue( 0),
iDoubleValue( 0.0)
{
AllocateSpace();
memcpy( iData, Source.iData, iSize);
}
void NumericValue::AllocateSpace()
{
switch(iNumericValueType)
{
case L_BYTE:
iData = new unsigned char [1];
iSize = 1;
break;
case L_WORD:
iData = new unsigned char [2];
iSize = 2;
break;
case L_LONG:
iData = new unsigned char [4];
iSize = 4;
break;
default:
if ( iNumericValueType != L_DOUBLE)
assert(0); // Cannot use NumericValue for specified data type.
}
if ( iNumericValueType != L_DOUBLE && iData == NULL)
{
ErrorHandler::OutputErrorLine( "Failed to allocate space for number.");
exit(1);
}
}
const unsigned char * NumericValue::Data() const
{
return iData;
}
unsigned long NumericValue::Size() const
{
return iSize;
}
DataType NumericValue::NumericValueType() const
{
return iNumericValueType;
}
void NumericValue::ConvertToNumber( const String & Source)
{
if ( iNumericValueType == L_DOUBLE)
ConvertToDouble( Source);
else
ConvertToNatural( Source);
}
void NumericValue::ConvertToDouble( const String & Source)
{
assert( iNumericValueType == L_DOUBLE);
assert( Source.Length() > 0);
double d = atof( Source.GetAssertedNonEmptyBuffer());
if ( d == 0.0 && !( Source == "0.0" || Source == "0") )
{ MOFF; cerr << "atof may have failed for " << Source << endl; MON;}
iDoubleValue = d;
}
#if defined(__VC32__)
#pragma warning( disable : 4706 ) // assignment within conditional expression
#endif
void NumericValue::ConvertToNatural( const String & Source)
{
unsigned long LongValue = 0;
assert( sizeof( unsigned long) >= 4); // Assume that LongValue can hold at least 2^32 - 1.
const char * pSourceChar = Source.iRep;
int bLeadingHyphen = 0;
int bHexNumber = 0;
if ( pSourceChar[0] == '0' && pSourceChar[1] == 'x')
{
bHexNumber = 1;
pSourceChar++;
pSourceChar++;
}
if ( pSourceChar[0] == '-')
{
bLeadingHyphen = 1;
pSourceChar++;
}
while ( * pSourceChar != '\0')
{
unsigned char DigitValue;
if ( bHexNumber)
{
assert( isxdigit( * pSourceChar) );
if ( isdigit( * pSourceChar) )
DigitValue = (unsigned char)(* pSourceChar - '0');
else
DigitValue = (unsigned char)(toupper( * pSourceChar) - 'A' + 10);
if (LongValue >= 0x10000000)
{
String st("Number \"");
st += Source;
st += "\" is too big ";
ErrorHandler::OutputErrorLine(st); //prevents overflow if number is bigger than 2^32 - 1.
}
LongValue = LongValue * 16 + DigitValue;
}
else
{
if ( ! isdigit( * pSourceChar) )
{
String s( "Cannot convert \"");
s += Source;
s += "\" to a number.";
ErrorHandler::OutputErrorLine( s);
exit(1);
// unreachable code
}
DigitValue = (unsigned char)(* pSourceChar - '0');
if ((LongValue > 429496729) || ((LongValue == 429496729) && (DigitValue > 5)))
{
String st("Number \"");
st += Source;
st += "\" is too big ";
ErrorHandler::OutputErrorLine(st); //prevents overflow if number is bigger than 2^32 - 1.
}
LongValue = LongValue * 10 + DigitValue;
}
pSourceChar++;
assert( ( pSourceChar - Source.iRep) < 10000); // Safety check!
}
int inrange=0;
// Check value is within the allowed range for the type taking into account
// a leading hyphen (minus sign) if there was one.
switch( iNumericValueType)
{
case L_BYTE: // L_BYTE is 8 bits long.
if ( bLeadingHyphen)
{
if ( ! ( inrange = (LongValue <= 128) ) ) // 2 ^ 7
ErrorHandler::OutputErrorLine( "Number too low for BYTE");
}
else
if ( ! ( inrange = (LongValue <= 0xFF) ) )
ErrorHandler::OutputErrorLine( "Number too big for BYTE");
break;
case L_WORD: // L_WORD is 16-bits long.
if ( bLeadingHyphen)
{
if ( ! ( inrange = (LongValue <= 32768) ) ) // 2^15
ErrorHandler::OutputErrorLine( "Number too low for WORD");
}
else
if ( ! ( inrange = (LongValue <= 0xFFFF) ) )
ErrorHandler::OutputErrorLine( "Number too big for WORD");
break;
case L_LONG: // L_LONG is 32-bits long
if ( bLeadingHyphen)
{
if ( ! ( inrange = (LongValue <= 0x80000000) ) ) // 2^31
ErrorHandler::OutputErrorLine( "Number too low for LONG");
}
else
if ( ! ( inrange = (LongValue <= 0xFFFFFFFF ) ) ) // This test is a bit pointless as long cannot be greater than 0xffffffff
ErrorHandler::OutputErrorLine( "Number too big for LONG");
break;
default:
assert(0); // Other data types cannot be converted to natural numbers.
}
if(!inrange)
exit(1);
StoreValue( LongValue);
// If there was a hyphen then make the stored number negative (using two's complement).
if ( bLeadingHyphen)
{
LongValue = (LongValue ^ 0xFFFFFFFFu)+1;
// Output file will be treated as little-endian.
switch ( iNumericValueType)
{
case L_LONG:
iData[3] = (unsigned char)((LongValue & 0xFF000000) >> 24);
iData[2] = (unsigned char)((LongValue & 0xFF0000) >> 16);
case L_WORD:
iData[1] = (unsigned char)((LongValue & 0xFF00) >> 8);
case L_BYTE:
iData[0] = (unsigned char)(LongValue & 0xFF);
}
}
}
#if defined(__VC32__)
#pragma warning( default : 4706 ) // assignment within conditional expression
#endif
void NumericValue::StoreValue( unsigned long LongValue)
{
iULongValue = LongValue;
if ( LongValue <= 0x80000000)
iSignedValue = (unsigned long) LongValue;
int inrange = 1;
switch( iNumericValueType)
{
case L_BYTE:
inrange = ( LongValue <= 0xFF);
break;
case L_WORD:
inrange = ( LongValue <= 0xFFFF);
break;
case L_LONG:
inrange = ( LongValue <= 0xFFFFFFFF);
}
if ( ! inrange)
{
ErrorHandler::OutputErrorLine( "Numeric value out of range for specified type");
exit(1);
}
// Output file will be treated as little-endian.
switch ( iNumericValueType)
{
case L_LONG:
iData[3] = (unsigned char)((LongValue & 0xFF000000) >> 24);
iData[2] = (unsigned char)((LongValue & 0xFF0000) >> 16);
case L_WORD:
iData[1] = (unsigned char)((LongValue & 0xFF00) >> 8);
case L_BYTE:
iData[0] = (unsigned char)(LongValue & 0xFF);
}
}
template<bool> class __CompileTimeAssert {public: __CompileTimeAssert(...) {}};
template<> class __CompileTimeAssert<false> {};
struct COMPILE_TIME_ERROR {};
#define COMPILE_TIME_ASSERT(aCondition) { __CompileTimeAssert<(aCondition)> __temp = __CompileTimeAssert<(aCondition)>(COMPILE_TIME_ERROR()); }
RCBinaryStream & operator<< ( RCBinaryStream & os, NumericValue o)
{
switch( o.iNumericValueType)
{
case L_BYTE:
os.Write( o.iData, 1);
break;
case L_WORD:
os.Write( o.iData, 2);
break;
case L_LONG:
os.Write( o.iData, 4);
break;
case L_DOUBLE:
COMPILE_TIME_ASSERT(sizeof(double) == 8);
os.Write(reinterpret_cast<unsigned char*>(&o.iDoubleValue), 8);
break;
default:
assert(0);
}
return os;
}
void NumericValue::StreamOut(ResourceDataStream& aStream) const
{
switch (iNumericValueType)
{
case L_BYTE:
aStream.StreamIn(iData, 1);
break;
case L_WORD:
aStream.StreamIn(iData, 2);
break;
case L_LONG:
aStream.StreamIn(iData, 4);
break;
case L_DOUBLE:
COMPILE_TIME_ASSERT(sizeof(double) == 8);
aStream.StreamIn(reinterpret_cast<const unsigned char*>(&iDoubleValue), 8);
break;
default:
assert(0);
}
}
NumericValue & NumericValue::operator= ( unsigned long ValueToSet)
{
StoreValue( ValueToSet);
return * this;
}
unsigned long NumericValue::GetULong() const
{
return iULongValue;
}
long NumericValue::GetLong() const
{
assert( iULongValue <= 2147483647); // Check that we are not holding a number that is really positive only.
return iSignedValue;
}
bool NumericValue::CheckSigned(unsigned long aValue, DataType aNumericValueType)
{
switch (aNumericValueType)
{
case L_BYTE:
if (aValue > 0x7f) return false;
break;
case L_WORD:
if (aValue > 0x7fff) return false;
break;
case L_LONG:
if (aValue > 0x7fffffff) return false;
break;
default:
assert(0);
}
return true;
}
String NumericValue::ltoa( long Source)
{
char v[10]; // long can have no more than 10 digits in this implementation.
char * pv = v;
long x;
if ( Source < 0)
x = - Source;
else
x = Source;
if ( x == 0)
* pv++ = '0';
else
{
while( x > 0)
{
assert( pv <= (v+9) );
* pv = char(x%10 + '0');
pv++;
x /= 10;
}
}
// Now reverse digits so they are in the correct order. Put in terminating null and hyphen
// if necessary.
char r[12];
char * pr = r;
if ( Source < 0)
{
r[0] = '-';
pr++;
}
while( pv != v)
{
assert( pr < (r+11) );
* pr++ = * --pv;
}
* pr = '\0';
return r;
}