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/*
* * thingdef_data . cpp
* *
* * DECORATE data tables
* *
* * - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
* * Copyright 2002 - 2008 Christoph Oelckers
* * Copyright 2004 - 2008 Randy Heit
* * All rights reserved .
* *
* * Redistribution and use in source and binary forms , with or without
* * modification , are permitted provided that the following conditions
* * are met :
* *
* * 1. Redistributions of source code must retain the above copyright
* * notice , this list of conditions and the following disclaimer .
* * 2. Redistributions in binary form must reproduce the above copyright
* * notice , this list of conditions and the following disclaimer in the
* * documentation and / or other materials provided with the distribution .
* * 3. The name of the author may not be used to endorse or promote products
* * derived from this software without specific prior written permission .
* *
* * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ` ` AS IS ' ' AND ANY EXPRESS OR
* * IMPLIED WARRANTIES , INCLUDING , BUT NOT LIMITED TO , THE IMPLIED WARRANTIES
* * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED .
* * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT , INDIRECT ,
* * INCIDENTAL , SPECIAL , EXEMPLARY , OR CONSEQUENTIAL DAMAGES ( INCLUDING , BUT
* * NOT LIMITED TO , PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES ; LOSS OF USE ,
* * DATA , OR PROFITS ; OR BUSINESS INTERRUPTION ) HOWEVER CAUSED AND ON ANY
* * THEORY OF LIABILITY , WHETHER IN CONTRACT , STRICT LIABILITY , OR TORT
* * ( INCLUDING NEGLIGENCE OR OTHERWISE ) ARISING IN ANY WAY OUT OF THE USE OF
* * THIS SOFTWARE , EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE .
* * - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
* *
*/
# include "zstring.h"
# include "vm.h"
# include "gstrings.h"
# include "v_font.h"
# include "types.h"
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# include "utf8.h"
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FString FStringFormat ( VM_ARGS , int offset )
{
PARAM_VA_POINTER ( va_reginfo ) // Get the hidden type information array
assert ( va_reginfo [ offset ] = = REGT_STRING ) ;
FString fmtstring = param [ offset ] . s ( ) . GetChars ( ) ;
param + = offset ;
numparam - = offset ;
va_reginfo + = offset ;
// note: we don't need a real printf format parser.
// enough to simply find the subtitution tokens and feed them to the real printf after checking types.
// https://en.wikipedia.org/wiki/Printf_format_string#Format_placeholder_specification
FString output ;
bool in_fmt = false ;
FString fmt_current ;
int argnum = 1 ;
int argauto = 1 ;
// % = starts
// [0-9], -, +, \s, 0, #, . continue
// %, s, d, i, u, fF, eE, gG, xX, o, c, p, aA terminate
// various type flags are not supported. not like stuff like 'hh' modifier is to be used in the VM.
// the only combination that is parsed locally is %n$...
bool haveargnums = false ;
for ( size_t i = 0 ; i < fmtstring . Len ( ) ; i + + )
{
char c = fmtstring [ i ] ;
if ( in_fmt )
{
if ( c = = ' * ' & & ( fmt_current . Len ( ) = = 1 | | ( fmt_current . Len ( ) = = 2 & & fmt_current [ 1 ] = = ' 0 ' ) ) )
{
fmt_current + = c ;
}
else if ( ( c > = ' 0 ' & & c < = ' 9 ' ) | |
c = = ' - ' | | c = = ' + ' | | ( c = = ' ' & & fmt_current . Back ( ) ! = ' ' ) | | c = = ' # ' | | c = = ' . ' )
{
fmt_current + = c ;
}
else if ( c = = ' $ ' ) // %number$format
{
if ( ! haveargnums & & argauto > 1 )
ThrowAbortException ( X_FORMAT_ERROR , " Cannot mix explicit and implicit arguments. " ) ;
FString argnumstr = fmt_current . Mid ( 1 ) ;
if ( ! argnumstr . IsInt ( ) ) ThrowAbortException ( X_FORMAT_ERROR , " Expected a numeric value for argument number, got '%s'. " , argnumstr . GetChars ( ) ) ;
auto argnum64 = argnumstr . ToLong ( ) ;
if ( argnum64 < 1 | | argnum64 > = numparam ) ThrowAbortException ( X_FORMAT_ERROR , " Not enough arguments for format (tried to access argument %d, %d total). " , argnum64 , numparam ) ;
fmt_current = " % " ;
haveargnums = true ;
argnum = int ( argnum64 ) ;
}
else
{
fmt_current + = c ;
switch ( c )
{
// string
case ' s ' :
{
if ( argnum < 0 & & haveargnums )
ThrowAbortException ( X_FORMAT_ERROR , " Cannot mix explicit and implicit arguments. " ) ;
in_fmt = false ;
// fail if something was found, but it's not a string
if ( argnum > = numparam ) ThrowAbortException ( X_FORMAT_ERROR , " Not enough arguments for format. " ) ;
if ( va_reginfo [ argnum ] ! = REGT_STRING ) ThrowAbortException ( X_FORMAT_ERROR , " Expected a string for format %s. " , fmt_current . GetChars ( ) ) ;
// append
output . AppendFormat ( fmt_current . GetChars ( ) , param [ argnum ] . s ( ) . GetChars ( ) ) ;
if ( ! haveargnums ) argnum = + + argauto ;
else argnum = - 1 ;
break ;
}
// pointer
case ' p ' :
{
if ( argnum < 0 & & haveargnums )
ThrowAbortException ( X_FORMAT_ERROR , " Cannot mix explicit and implicit arguments. " ) ;
in_fmt = false ;
// fail if something was found, but it's not a string
if ( argnum > = numparam ) ThrowAbortException ( X_FORMAT_ERROR , " Not enough arguments for format. " ) ;
if ( va_reginfo [ argnum ] ! = REGT_POINTER ) ThrowAbortException ( X_FORMAT_ERROR , " Expected a pointer for format %s. " , fmt_current . GetChars ( ) ) ;
// append
output . AppendFormat ( fmt_current . GetChars ( ) , param [ argnum ] . a ) ;
if ( ! haveargnums ) argnum = + + argauto ;
else argnum = - 1 ;
break ;
}
// int formats (including char)
case ' d ' :
case ' i ' :
case ' u ' :
case ' x ' :
case ' X ' :
case ' o ' :
case ' c ' :
case ' B ' :
{
if ( argnum < 0 & & haveargnums )
ThrowAbortException ( X_FORMAT_ERROR , " Cannot mix explicit and implicit arguments. " ) ;
in_fmt = false ;
// append
if ( fmt_current [ 1 ] = = ' * ' | | fmt_current [ 2 ] = = ' * ' )
{
// fail if something was found, but it's not an int
if ( argnum + 1 > = numparam ) ThrowAbortException ( X_FORMAT_ERROR , " Not enough arguments for format. " ) ;
if ( va_reginfo [ argnum ] ! = REGT_INT & &
va_reginfo [ argnum ] ! = REGT_FLOAT ) ThrowAbortException ( X_FORMAT_ERROR , " Expected a numeric value for format %s. " , fmt_current . GetChars ( ) ) ;
if ( va_reginfo [ argnum + 1 ] ! = REGT_INT & &
va_reginfo [ argnum + 1 ] ! = REGT_FLOAT ) ThrowAbortException ( X_FORMAT_ERROR , " Expected a numeric value for format %s. " , fmt_current . GetChars ( ) ) ;
output . AppendFormat ( fmt_current . GetChars ( ) , param [ argnum ] . ToInt ( va_reginfo [ argnum ] ) , param [ argnum + 1 ] . ToInt ( va_reginfo [ argnum + 1 ] ) ) ;
argauto + + ;
}
else
{
// fail if something was found, but it's not an int
if ( argnum > = numparam ) ThrowAbortException ( X_FORMAT_ERROR , " Not enough arguments for format. " ) ;
if ( va_reginfo [ argnum ] ! = REGT_INT & &
va_reginfo [ argnum ] ! = REGT_FLOAT ) ThrowAbortException ( X_FORMAT_ERROR , " Expected a numeric value for format %s. " , fmt_current . GetChars ( ) ) ;
output . AppendFormat ( fmt_current . GetChars ( ) , param [ argnum ] . ToInt ( va_reginfo [ argnum ] ) ) ;
}
if ( ! haveargnums ) argnum = + + argauto ;
else argnum = - 1 ;
break ;
}
// double formats
case ' f ' :
case ' F ' :
case ' e ' :
case ' E ' :
case ' g ' :
case ' G ' :
case ' a ' :
case ' A ' :
{
if ( argnum < 0 & & haveargnums )
ThrowAbortException ( X_FORMAT_ERROR , " Cannot mix explicit and implicit arguments. " ) ;
in_fmt = false ;
if ( fmt_current [ 1 ] = = ' * ' | | fmt_current [ 2 ] = = ' * ' )
{
// fail if something was found, but it's not an int
if ( argnum + 1 > = numparam ) ThrowAbortException ( X_FORMAT_ERROR , " Not enough arguments for format. " ) ;
if ( va_reginfo [ argnum ] ! = REGT_INT & &
va_reginfo [ argnum ] ! = REGT_FLOAT ) ThrowAbortException ( X_FORMAT_ERROR , " Expected a numeric value for format %s. " , fmt_current . GetChars ( ) ) ;
if ( va_reginfo [ argnum + 1 ] ! = REGT_INT & &
va_reginfo [ argnum + 1 ] ! = REGT_FLOAT ) ThrowAbortException ( X_FORMAT_ERROR , " Expected a numeric value for format %s. " , fmt_current . GetChars ( ) ) ;
output . AppendFormat ( fmt_current . GetChars ( ) , param [ argnum ] . ToInt ( va_reginfo [ argnum ] ) , param [ argnum + 1 ] . ToDouble ( va_reginfo [ argnum + 1 ] ) ) ;
argauto + + ;
}
else
{
// fail if something was found, but it's not a float
if ( argnum > = numparam ) ThrowAbortException ( X_FORMAT_ERROR , " Not enough arguments for format. " ) ;
if ( va_reginfo [ argnum ] ! = REGT_INT & &
va_reginfo [ argnum ] ! = REGT_FLOAT ) ThrowAbortException ( X_FORMAT_ERROR , " Expected a numeric value for format %s. " , fmt_current . GetChars ( ) ) ;
// append
output . AppendFormat ( fmt_current . GetChars ( ) , param [ argnum ] . ToDouble ( va_reginfo [ argnum ] ) ) ;
}
if ( ! haveargnums ) argnum = + + argauto ;
else argnum = - 1 ;
break ;
}
default :
// invalid character
output + = fmt_current ;
in_fmt = false ;
break ;
}
}
}
else
{
if ( c = = ' % ' )
{
if ( i + 1 < fmtstring . Len ( ) & & fmtstring [ i + 1 ] = = ' % ' )
{
output + = ' % ' ;
i + + ;
}
else
{
in_fmt = true ;
fmt_current = " % " ;
}
}
else
{
output + = c ;
}
}
}
return output ;
}
DEFINE_ACTION_FUNCTION ( FStringStruct , Format )
{
PARAM_PROLOGUE ;
FString s = FStringFormat ( VM_ARGS_NAMES ) ;
ACTION_RETURN_STRING ( s ) ;
}
DEFINE_ACTION_FUNCTION ( FStringStruct , AppendFormat )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
// first parameter is the self pointer
FString s = FStringFormat ( VM_ARGS_NAMES , 1 ) ;
( * self ) + = s ;
return 0 ;
}
DEFINE_ACTION_FUNCTION ( FStringStruct , AppendCharacter )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_INT ( c ) ;
self - > AppendCharacter ( c ) ;
return 0 ;
}
DEFINE_ACTION_FUNCTION ( FStringStruct , DeleteLastCharacter )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
self - > DeleteLastCharacter ( ) ;
return 0 ;
}
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//=====================================================================================
//
// FString exports
//
//=====================================================================================
static void LocalizeString ( const FString & label , bool prefixed , FString * result )
{
if ( ! prefixed ) * result = GStrings ( label ) ;
else if ( label [ 0 ] ! = ' $ ' ) * result = label ;
else * result = GStrings ( & label [ 1 ] ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringTable , Localize , LocalizeString )
{
PARAM_PROLOGUE ;
PARAM_STRING ( label ) ;
PARAM_BOOL ( prefixed ) ;
FString result ;
LocalizeString ( label , prefixed , & result ) ;
ACTION_RETURN_STRING ( result ) ;
}
static void StringReplace ( FString * self , const FString & s1 , const FString & s2 )
{
self - > Substitute ( s1 , s2 ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , Replace , StringReplace )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_STRING ( s1 ) ;
PARAM_STRING ( s2 ) ;
self - > Substitute ( s1 , s2 ) ;
return 0 ;
}
static void StringMid ( FString * self , unsigned pos , unsigned len , FString * result )
{
* result = self - > Mid ( pos , len ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , Mid , StringMid )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_UINT ( pos ) ;
PARAM_UINT ( len ) ;
FString s = self - > Mid ( pos , len ) ;
ACTION_RETURN_STRING ( s ) ;
}
static void StringLeft ( FString * self , unsigned len , FString * result )
{
* result = self - > Left ( len ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , Left , StringLeft )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_UINT ( len ) ;
FString s = self - > Left ( len ) ;
ACTION_RETURN_STRING ( s ) ;
}
static void StringTruncate ( FString * self , unsigned len )
{
self - > Truncate ( len ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , Truncate , StringTruncate )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_UINT ( len ) ;
self - > Truncate ( len ) ;
return 0 ;
}
static void StringRemove ( FString * self , unsigned index , unsigned remlen )
{
self - > Remove ( index , remlen ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , Remove , StringRemove )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_UINT ( index ) ;
PARAM_UINT ( remlen ) ;
self - > Remove ( index , remlen ) ;
return 0 ;
}
static void StringCharAt ( FString * self , int pos , FString * result )
{
if ( ( unsigned ) pos > = self - > Len ( ) ) * result = " " ;
else * result = FString ( ( * self ) [ pos ] ) ;
}
// CharAt and CharCodeAt is how JS does it, and JS is similar here in that it doesn't have char type as int.
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , CharAt , StringCharAt )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_INT ( pos ) ;
FString result ;
StringCharAt ( self , pos , & result ) ;
ACTION_RETURN_STRING ( result ) ;
}
static int StringCharCodeAt ( FString * self , int pos )
{
if ( ( unsigned ) pos > = self - > Len ( ) ) return 0 ;
else return ( * self ) [ pos ] ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , CharCodeAt , StringCharCodeAt )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_INT ( pos ) ;
ACTION_RETURN_INT ( StringCharCodeAt ( self , pos ) ) ;
}
static int StringByteAt ( FString * self , int pos )
{
if ( ( unsigned ) pos > = self - > Len ( ) ) return 0 ;
else return ( uint8_t ) ( ( * self ) [ pos ] ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , ByteAt , StringByteAt )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_INT ( pos ) ;
ACTION_RETURN_INT ( StringByteAt ( self , pos ) ) ;
}
static void StringFilter ( FString * self , FString * result )
{
* result = strbin1 ( * self ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , Filter , StringFilter )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
ACTION_RETURN_STRING ( strbin1 ( * self ) ) ;
}
static int StringIndexOf ( FString * self , const FString & substr , int startIndex )
{
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return ( int ) self - > IndexOf ( substr , startIndex ) ;
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}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , IndexOf , StringIndexOf )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_STRING ( substr ) ;
PARAM_INT ( startIndex ) ;
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ACTION_RETURN_INT ( StringIndexOf ( self , substr , startIndex ) ) ;
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}
static int StringLastIndexOf ( FString * self , const FString & substr , int endIndex )
{
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return ( int ) self - > LastIndexOfBroken ( substr , endIndex ) ;
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}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , LastIndexOf , StringLastIndexOf )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_STRING ( substr ) ;
PARAM_INT ( endIndex ) ;
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ACTION_RETURN_INT ( StringLastIndexOf ( self , substr , endIndex ) ) ;
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}
static int StringRightIndexOf ( FString * self , const FString & substr , int endIndex )
{
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return ( int ) self - > LastIndexOf ( substr , endIndex ) ;
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}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , RightIndexOf , StringRightIndexOf )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_STRING ( substr ) ;
PARAM_INT ( endIndex ) ;
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ACTION_RETURN_INT ( StringRightIndexOf ( self , substr , endIndex ) ) ;
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}
static void StringToUpper ( FString * self )
{
self - > ToUpper ( ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , ToUpper , StringToUpper )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
self - > ToUpper ( ) ;
return 0 ;
}
static void StringToLower ( FString * self )
{
self - > ToLower ( ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , ToLower , StringToLower )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
self - > ToLower ( ) ;
return 0 ;
}
static void StringMakeUpper ( FString * self , FString * out )
{
* out = self - > MakeUpper ( ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , MakeUpper , StringMakeUpper )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
ACTION_RETURN_STRING ( self - > MakeUpper ( ) ) ;
}
static void StringMakeLower ( FString * self , FString * out )
{
* out = self - > MakeLower ( ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , MakeLower , StringMakeLower )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
ACTION_RETURN_STRING ( self - > MakeLower ( ) ) ;
}
static int StringCharUpper ( int ch )
{
return ch > = 0 & & ch < 65536 ? upperforlower [ ch ] : ch ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , CharUpper , StringCharUpper )
{
PARAM_PROLOGUE ;
PARAM_INT ( ch ) ;
ACTION_RETURN_INT ( StringCharUpper ( ch ) ) ;
}
static int StringCharLower ( int ch )
{
return ch > = 0 & & ch < 65536 ? lowerforupper [ ch ] : ch ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , CharLower , StringCharLower )
{
PARAM_PROLOGUE ;
PARAM_INT ( ch ) ;
ACTION_RETURN_INT ( StringCharLower ( ch ) ) ;
}
static int StringToInt ( FString * self , int base )
{
return ( int ) self - > ToLong ( base ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , ToInt , StringToInt )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_INT ( base ) ;
ACTION_RETURN_INT ( ( int ) self - > ToLong ( base ) ) ;
}
static double StringToDbl ( FString * self )
{
return self - > ToDouble ( ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , ToDouble , StringToDbl )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
ACTION_RETURN_FLOAT ( self - > ToDouble ( ) ) ;
}
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static void StringSubst ( FString * self , const FString & substr , const FString & replc )
{
self - > Substitute ( substr , replc ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , Substitute , StringSubst )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_STRING ( substr ) ;
PARAM_STRING ( replc ) ;
StringSubst ( self , substr , replc ) ;
return 0 ;
}
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static void StringStripRight ( FString * self , const FString & junk )
{
if ( junk . IsNotEmpty ( ) ) self - > StripRight ( junk ) ;
else self - > StripRight ( ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , StripRight , StringStripRight )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_STRING ( junk ) ;
StringStripRight ( self , junk ) ;
return 0 ;
}
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static void StringStripLeft ( FString * self , const FString & junk )
{
if ( junk . IsNotEmpty ( ) ) self - > StripLeft ( junk ) ;
else self - > StripLeft ( ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , StripLeft , StringStripLeft )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_STRING ( junk ) ;
StringStripLeft ( self , junk ) ;
return 0 ;
}
static void StringStripLeftRight ( FString * self , const FString & junk )
{
if ( junk . IsNotEmpty ( ) ) self - > StripLeftRight ( junk ) ;
else self - > StripLeftRight ( ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , StripLeftRight , StringStripLeftRight )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_STRING ( junk ) ;
StringStripLeftRight ( self , junk ) ;
return 0 ;
}
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static void StringSplit ( FString * self , TArray < FString > * tokens , const FString & delimiter , int keepEmpty )
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{
self - > Split ( * tokens , delimiter , static_cast < FString : : EmptyTokenType > ( keepEmpty ) ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , Split , StringSplit )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_POINTER ( tokens , TArray < FString > ) ;
PARAM_STRING ( delimiter ) ;
PARAM_INT ( keepEmpty ) ;
StringSplit ( self , tokens , delimiter , keepEmpty ) ;
return 0 ;
}
static int StringCodePointCount ( FString * self )
{
return ( int ) self - > CharacterCount ( ) ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , CodePointCount , StringCodePointCount )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
ACTION_RETURN_INT ( StringCodePointCount ( self ) ) ;
}
static int StringNextCodePoint ( FString * self , int inposition , int * position )
{
int codepoint = self - > GetNextCharacter ( inposition ) ;
if ( position ) * position = inposition ;
return codepoint ;
}
DEFINE_ACTION_FUNCTION_NATIVE ( FStringStruct , GetNextCodePoint , StringNextCodePoint )
{
PARAM_SELF_STRUCT_PROLOGUE ( FString ) ;
PARAM_INT ( pos ) ;
if ( numret > 0 ) ret [ 0 ] . SetInt ( self - > GetNextCharacter ( pos ) ) ;
if ( numret > 1 ) ret [ 1 ] . SetInt ( pos ) ;
return numret ;
}