DPDEF142718 Incremental rebuild fails if dependent files deleted (resurrection through merge).
/*
* 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:
* STRING.CPP
*
*/
#include <stdio.h>
#include <string.h>
#include <assert.h>
#include <ctype.h>
#include "CTABLE.H" // character code mapping classes
#include "ASTRING.H"
extern Mapping_range CP1252_exceptions;
// table of exceptions from CP1252 1:1 mapping with Unicode.
#undef STRING_DEBUG
String::String()
{
iLength=0;
iRep=NULL;
}
String::String(const char* aText)
{
ArrayItem();
iLength=strlen(aText);
iRep=new char[iLength+1];
assert(iRep!=NULL);
strcpy(iRep,aText);
}
String::String(const String& SourceString): ArrayItem(SourceString)
{
iLength=SourceString.iLength;
iRep=new char[ iLength + 1];
assert( iRep != 0);
if(iLength==0) *iRep='\0';
else strcpy( iRep, SourceString.iRep);
}
String::~String()
{
delete [] iRep;
}
void String::Reset()
{
iLength=0;
delete [] iRep;
iRep=NULL;
}
char& String::operator[] (unsigned long CharIndex) const
{
if ( CharIndex > iLength)
{
assert( 0);
return iRep[ iLength]; // i.e. \0
}
return iRep[ CharIndex];
}
String& String::operator=(const String& SourceString)
{
if(&SourceString==this)
return *this;
delete [] iRep;
iLength=SourceString.iLength;
if ( iLength == 0)
{
iRep=NULL;
return * this;
}
iRep=new char [ iLength + 1];
assert( iRep != NULL);
strcpy( iRep, SourceString.iRep);
return *this;
}
String& String::operator+= (const String & SourceString)
{
char * pOldRep=iRep;
iLength += SourceString.iLength;
if ( iLength == 0)
iRep=NULL;
else
{
iRep=new char [ iLength + 1];
assert( iRep != NULL);
strcpy( iRep, pOldRep);
strcpy( iRep + strlen( pOldRep), SourceString.iRep);
}
delete [] pOldRep;
return *this;
}
int String::operator== (const String & CompareString) const
{
return(!strcmp( iRep, CompareString.iRep));
}
int String::operator!= (const String & CompareString) const
{
return(strcmp( iRep, CompareString.iRep));
}
unsigned long String::Length() const
{
return iLength;
}
ostream& operator<< ( ostream& os, const String & a)
{
return ( os << ( ( a.iLength <= 0) ? "<empty>" : a.iRep) );
}
const char * String::GetBuffer() const
{
assert (iRep != NULL);
return iRep;
}
const char * String::GetAssertedNonEmptyBuffer() const
{
assert( iRep != NULL);
assert( iLength > 0);
return iRep;
}
int String::IsDecNatural() const
{
assert( iLength > 0);
unsigned long i=0;
if ( iRep[0] == '-')
i++;
for( ; i < iLength; i++)
{
if (!isdigit( iRep[i]) )
return 0; // Non-digit found.
}
return 1; // Successful - all numeric.
}
String & String::Upper()
{
for(unsigned long i=0;i<iLength;i++)
iRep[i]=char(toupper(iRep[i]));
return *this;
}
String String::operator+ (const String & SecondString) const
{
String s;
s.iLength=iLength + SecondString.iLength;
s.iRep=new char[ s.iLength + 1];
strcpy( s.iRep, iRep);
strcpy( s.iRep + iLength, SecondString.iRep);
return s;
}
bool StringLess::operator()(const String& aLeft, const String& aRight) const
{
const char* bufferLeft = aLeft.GetBuffer();
const char* bufferRight = aRight.GetBuffer();
for (;;)
{
if (*bufferLeft != *bufferRight || *bufferLeft == 0)
return *bufferLeft < *bufferRight;
++bufferLeft;
++bufferRight;
}
}
const unsigned char* String::UCRep (unsigned long aIndex) const
{
return (const unsigned char*)&iRep[aIndex];
}
static UTF32 getUTF8(const unsigned char* aUtfByte, unsigned int& aIndex, unsigned int aMax)
{
unsigned char utfByte = *aUtfByte++;
aIndex +=1;
UTF32 unicodeChar = (UTF32) utfByte;
// Slightly cavalier decoding - always write something
// and don't consume bytes which don't fit the pattern!
if ((utfByte & 0xe0) == 0xc0)
{
unicodeChar = (UTF16)((utfByte&0x1f)<<6);
if (aIndex < aMax)
{
utfByte = (unsigned char)(*aUtfByte++);
if ((utfByte&0xc0)==0x80)
{
unicodeChar |= (utfByte&0x3f);
aIndex +=1;
}
}
}
else
if ((utfByte & 0xf0) == 0xe0)
{
unicodeChar = (UTF16)((utfByte&0x0f)<<12);
if (aIndex < aMax)
{
utfByte = (unsigned char)(*aUtfByte++);
if ((utfByte&0xc0)==0x80)
{
unicodeChar |= (utfByte&0x3f)<<6;
aIndex +=1;
}
}
if (aIndex < aMax)
{
utfByte = (unsigned char)(*aUtfByte++);
if ((utfByte&0xc0)==0x80)
{
unicodeChar |= (utfByte&0x3f);
aIndex +=1;
}
}
}
else if ((utfByte & 0xF8) == 0xF0) // 4 bytes UTF-8
{
unicodeChar = (UTF32)((utfByte & 0x07) << 18);
if (aIndex < aMax)
{
utfByte = (unsigned char)(*aUtfByte++);
if ((utfByte&0xc0)==0x80)
{
unicodeChar |= (utfByte&0x3f)<<12;
aIndex +=1;
}
}
if (aIndex < aMax)
{
utfByte = (unsigned char)(*aUtfByte++);
if ((utfByte&0xc0)==0x80)
{
unicodeChar |= (utfByte&0x3f)<<6;
aIndex +=1;
}
}
if (aIndex < aMax)
{
utfByte = (unsigned char)(*aUtfByte++);
if ((utfByte&0xc0)==0x80)
{
unicodeChar |= (utfByte&0x3f);
aIndex +=1;
}
}
}
return unicodeChar;
}
int String::FindSubString(String aSubString, int aStart)
{
for(unsigned int j=aStart; j<iLength - aSubString.Length() + 1; j++)
{
bool match = true;
for(unsigned int k=0; k< aSubString.Length(); k++)
if(iRep[j+k]!=aSubString[k])
match = false;
if(match) return j;
}
return EStringNotFound;
}
String String::ExtractSubString(const unsigned int aStart, const unsigned int aFinish)
{
// ensure that the passed bounds are valid
if( aStart > iLength )
{
String substr = "";
return substr;
}
else if( aFinish > iLength ) {
assert( !"This condition should never happen" );
String substr = "";
return substr;
}
else if( aStart > aFinish ) {
assert( !"This condition should never happen" );
String substr = "";
return substr;
}
// if valid - go and copy everything
else {
char *char_substr = &(iRep[aStart]);
char temp_char = iRep[aFinish + 1];
iRep[aFinish + 1] = 0;
String substr( char_substr );
iRep[aFinish + 1] = temp_char;
return substr;
}
}
String& String::operator+= (char * SourceChar)
{
char * pOldRep = iRep;
iLength += strlen(SourceChar);
iRep = new char [iLength + 1];
strcpy( iRep, pOldRep);
strcpy( iRep + iLength-strlen(SourceChar), SourceChar);
delete [] pOldRep;
return * this;
}
int String::Atoi()
{
return atoi(iRep);
}
int String::Export( UTF16 *buffer, int& length, CharacterSet fromchset ) const
// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
//
// Export the string from its internal form to the caller supplied buffer
// (which in this case is meant to be Unicode). On entry, length indicates
// the number of characters in the buffer. On exit, this is set to the number
// of characters actually written. The export involves mapping from the
// specified character set to Unicode.
//
// The return value is normally TRUE. If not, truncation has occurred.
//
//
// NB, this function is currently under development and character set
// mapping is not yet properly implemented.
// NB2. it's also largely duplicated in String::ExportLength, which should
// be updated to match...
// ---------------------------------------------------------------------------
{
unsigned int index = 0; // index into internal buffer
int outcount = 0; // count of characters written to export buffer
for(int i=0;i<length;i++)
{
buffer[i] = 0;
}
// Because of multibyte character sets, the general code pattern for
// copying the characters has to work left to right to allow for
// byte sequence interpretation. The raw byte count of such a string
// can be greater than the number of characters it represents.
switch ( fromchset )
{
case CP1252:
// In this case, we know that there is only a narrow range
// of characters that aren't a direct mapping.
while ( (index < iLength) && ( outcount < length ) )
{
// To allow for direct Unicode characters in CP1252 strings, we
// insert a special character followed by the UTF8 sequence
if (*UCRep(index) == UnicodeEscape)
{
index +=1;
if (index < iLength)
{
buffer[outcount] = getUTF8(UCRep(index), index, iLength);
}
}
else
{
buffer[outcount] = *UCRep(index);
index +=1;
}
// Now, see if the character ended up in the forbidden range. If so, map
// it to the correct Unicode character.
if ( buffer[outcount] < 255 )
{
unsigned char temp;
temp = (unsigned char)buffer[outcount];
CP1252_exceptions.map(temp, buffer[outcount]);
}
outcount += 1;
} // end of loop to export characters
break;
case UTF8:
while ( (index < iLength) && ( outcount < length ) )
{
UTF32 tu32 = getUTF8(UCRep(index), index, iLength);
if (tu32 <= 0xFFFF)
{
buffer[outcount] = tu32;
outcount +=1;
}
else
{
if ( tu32 > 0x10ffff )
{
printf("Surrogate character code must be a number in the range 0x10000 to 0x10ffff\n");
printf("Error: rcomp.exe line %d\n", __LINE__);
}
buffer[outcount] = (UTF16)(0xD7C0 + (tu32 >> 10)); // high surrogate
outcount++;
if (outcount < length)
{
buffer[outcount] = (UTF16)(0xDC00 | (tu32 & 0x3FF)); // low surrogate
outcount++;
}
else
{
printf("Error: rcomp.exe line %d\n", __LINE__);
}
}
} // end of loop to export characters
break;
default: // this should eventually become an exception
while ( (index < iLength) && ( outcount < length ) )
{
buffer[outcount] = *UCRep(index);
outcount +=1;
index += 1;
} // end of loop to export characters
break;
} // end of switch on character set.
length = outcount;
// If the index is not now equal to the internal length then
// the string was truncated on export.
if ( index != iLength ) return 0; else return 1;
} // end of Export to Unicode function.
// What length of exported text does this String represent?
unsigned long String::ExportLength (CharacterSet tochset, CharacterSet fromchset) const
{
if (tochset != Unicode)
return iLength;
unsigned int index = 0; // index into internal buffer
unsigned long outcount = 0; // count of output characters
switch ( fromchset )
{
case CP1252:
// In this case, we know that there is only a narrow range
// of characters that aren't a direct mapping.
while ( (index < iLength) )
{
// To allow for direct Unicode characters in CP1252 strings, we
// insert a special character followed by the UTF8 sequence
if (*UCRep(index) == UnicodeEscape)
{
index +=1;
if (index < iLength)
{
(void) getUTF8(UCRep(index), index, iLength);
}
}
else
{
index +=1;
}
outcount += 1;
}
break;
case UTF8:
while ( (index < iLength) )
{
UTF32 tu32 = getUTF8(UCRep(index), index, iLength);
outcount +=1;
if (tu32 > 0xFFFF)
++outcount;
}
break;
default: // this should eventually become an exception
outcount = iLength;
break;
} // end of switch on character set.
return outcount;
}
// end of ASTRING.CPP