Team Fortress 2 Source Code as on 22/4/2020
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//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose:
//
// $NoKeywords: $
//=============================================================================//
#include <assert.h>
#include "stdafx.h"
#include <stdio.h>
#include <windows.h>
#include "classcheck_util.h"
#include "class.h"
#include "icodeprocessor.h"
CClass::CClass( const char *name )
{
m_nVarCount = 0;
m_nMemberCount = 0;
m_nTDCount = 0;
m_nPredTDCount = 0;
strcpy( m_szName, name );
m_szBaseClass[0]=0;
m_pBaseClass = NULL;
m_szTypedefBaseClass[0]=0;
m_bDerivedFromCBaseEntity = false;
m_bHasSaveRestoreData = false;
m_bHasPredictionData = false;
m_bConstructPredictableCalled = false;
m_bHasRecvTableData = false;
m_nClassDataSize = 0;
}
CClass::~CClass( void )
{
int i;
for ( i = 0; i < m_nVarCount; i++ )
{
delete m_Variables[ i ];
}
m_nVarCount = 0;
for ( i = 0; i < m_nMemberCount; i++ )
{
delete m_Members[ i ];
}
m_nMemberCount = 0;
for ( i = 0; i < m_nTDCount; i++ )
{
delete m_TDFields[ i ];
}
m_nTDCount = 0;
for ( i = 0; i < m_nPredTDCount; i++ )
{
delete m_PredTDFields[ i ];
}
m_nPredTDCount = 0;
}
CTypeDescriptionField *CClass::FindTD( const char *name )
{
for ( int i = 0; i < m_nTDCount; i++ )
{
if ( !strcmp( m_TDFields[ i ]->m_szVariableName, name ) )
return m_TDFields[ i ];
}
return NULL;
}
CTypeDescriptionField *CClass::FindPredTD( const char *name )
{
for ( int i = 0; i < m_nPredTDCount; i++ )
{
if ( !strcmp( m_PredTDFields[ i ]->m_szVariableName, name ) )
return m_PredTDFields[ i ];
}
return NULL;
}
CClassVariable *CClass::FindVar( const char *name, bool checkbaseclasses /*= false*/ )
{
CClass *cl = this;
while ( cl )
{
for ( int i = 0; i < cl->m_nVarCount; i++ )
{
if ( !strcmp( cl->m_Variables[ i ]->m_szName, name ) )
return cl->m_Variables[ i ];
}
if ( !checkbaseclasses )
break;
if ( !cl->m_pBaseClass )
{
cl->m_pBaseClass = processor->FindClass( cl->m_szBaseClass );
}
cl = cl->m_pBaseClass;
if ( !cl )
break;
}
return NULL;
}
CClassMemberFunction *CClass::FindMember( const char *name )
{
for ( int i = 0; i < m_nMemberCount; i++ )
{
if ( !strcmp( m_Members[ i ]->m_szName, name ) )
return m_Members[ i ];
}
return NULL;
}
CTypeDescriptionField *CClass::AddTD( const char *name, const char *type, const char *definetype, bool incomments )
{
CTypeDescriptionField *td = FindTD( name );
if ( !td )
{
td = new CTypeDescriptionField();
strcpy( td->m_szVariableName, name );
strcpy( td->m_szType, type );
strcpy( td->m_szDefineType, definetype );
td->m_bCommentedOut = incomments;
m_TDFields[ m_nTDCount++ ] = td;
if ( m_nTDCount >= MAX_TDFIELDS )
{
vprint( 0, "too many typedescription fields\n" );
exit( 1 );
}
}
return td;
}
CTypeDescriptionField *CClass::AddPredTD( const char *name, const char *type, const char *definetype, bool incomments, bool inrecvtable )
{
CTypeDescriptionField *td = FindPredTD( name );
if ( !td )
{
td = new CTypeDescriptionField();
strcpy( td->m_szVariableName, name );
strcpy( td->m_szType, type );
strcpy( td->m_szDefineType, definetype );
td->m_bCommentedOut = incomments;
td->m_bRepresentedInRecvTable = inrecvtable;
m_PredTDFields[ m_nPredTDCount++ ] = td;
if ( m_nPredTDCount >= MAX_TDFIELDS )
{
vprint( 0, "too many prediction typedescription fields\n" );
exit( 1 );
}
}
return td;
}
CClassVariable *CClass::AddVar( const char *name )
{
CClassVariable *var = FindVar( name );
if ( !var )
{
var = new CClassVariable();
strcpy( var->m_szName, name );
m_Variables[ m_nVarCount++ ] = var;
if ( m_nVarCount >= MAX_VARIABLES )
{
vprint( 0, "too many variables\n" );
exit( 1 );
}
}
return var;
}
CClassMemberFunction *CClass::AddMember( const char *name )
{
CClassMemberFunction *member = FindMember( name );
if ( !member )
{
member = new CClassMemberFunction();
strcpy( member->m_szName, name );
m_Members[ m_nMemberCount++ ] = member;
if ( m_nMemberCount >= MAX_MEMBERS )
{
vprint( 0, "too many members\n" );
exit( 1 );
}
}
return member;
}
void CClass::SetBaseClass( const char *name )
{
if ( !m_szBaseClass[ 0 ] )
{
strcpy( m_szBaseClass, name );
}
else if ( stricmp( m_szBaseClass, name ) )
{
vprint( 0, "Base class differs for %s %s vs %s\n", m_szName, m_szBaseClass, name );
}
}
void CClass::CheckChildOfBaseEntity( const char *baseentityclass )
{
m_bDerivedFromCBaseEntity = false;
if ( !stricmp( m_szName, baseentityclass ) )
{
m_bDerivedFromCBaseEntity = true;
return;
}
CClass *base = m_pBaseClass;
while ( base )
{
// Early out?
if ( base->m_bDerivedFromCBaseEntity )
{
m_bDerivedFromCBaseEntity = true;
return;
}
// Check name
if ( !stricmp( base->m_szName, baseentityclass ) )
{
m_bDerivedFromCBaseEntity = true;
return;
}
// Keep going up hierarchy
base = base->m_pBaseClass;
}
}
static bool IsType( char *input, char *test )
{
char *pMatch = strstr( input, test );
if ( !pMatch )
return false;
size_t nLen = strlen(test);
if ( ( pMatch[nLen] != 0 ) && (pMatch[nLen] != ' ') )
return false;
if ( input != pMatch && (*(pMatch-1) != ' ') )
return false;
return true;
}
static char const *TranslateSimpleType( CClassVariable *var )
{
static char out[ 256 ];
out[ 0 ] = 0;
char *input = var->m_szType;
// Don't know how to handle templatized things yet
if ( strstr( input, "<" ) )
{
return out;
}
if ( IsType( input, "bool" ) )
{
return "FIELD_BOOLEAN";
}
else if ( IsType( input, "short" ) )
{
return "FIELD_SHORT";
}
else if ( IsType( input, "int" ) )
{
return "FIELD_INTEGER";
}
else if ( IsType( input, "byte" ) )
{
return "FIELD_CHARACTER";
}
else if ( IsType( input, "float" ) )
{
return "FIELD_FLOAT";
}
else if ( IsType( input, "EHANDLE" ) || IsType( input, "CHandle" ) )
{
return "FIELD_EHANDLE";
}
else if ( IsType( input, "color32" ) )
{
return "FIELD_COLOR32";
}
else if ( IsType( input, "Vector" ) || IsType( input, "QAngle" ) )
{
return "FIELD_VECTOR";
}
else if ( IsType( input, "Quaternion" ) )
{
return "FIELD_QUATERNION";
}
else if ( IsType( input, "VMatrix" ) )
{
return "FIELD_VMATRIX";
}
else if ( IsType( input, "string_t" ) )
{
return "FIELD_STRING";
}
else if ( IsType( input, "char" ) )
{
return "FIELD_CHARACTER";
}
return out;
}
void CClass::ReportTypeMismatches( CClassVariable *var, CTypeDescriptionField *td )
{
char const *t = TranslateSimpleType( var );
if ( !t[0] )
return;
// Special cases
if ( td->m_bCommentedOut )
return;
if ( !strcmp( td->m_szType, "FIELD_TIME" ) )
{
if ( !strcmp( t, "FIELD_FLOAT" ) )
return;
}
if ( !strcmp( td->m_szType, "FIELD_TICK" ) )
{
if ( !strcmp( t, "FIELD_INTEGER" ) )
return;
}
if ( !strcmp( td->m_szType, "FIELD_MODELNAME" ) || !strcmp( td->m_szType, "FIELD_SOUNDNAME" ) )
{
if ( !strcmp( t, "FIELD_STRING" ) )
return;
}
if ( !strcmp( td->m_szType, "FIELD_MODELINDEX" ) || !strcmp( td->m_szType, "FIELD_MATERIALINDEX" ) )
{
if ( !strcmp( t, "FIELD_INTEGER" ) )
return;
}
if ( !strcmp( td->m_szType, "FIELD_POSITION_VECTOR" ) )
{
if ( !strcmp( t, "FIELD_VECTOR" ) )
return;
}
if ( !strcmp( td->m_szType, "FIELD_VMATRIX_WORLDSPACE" ) )
{
if ( !strcmp( t, "FIELD_VMATRIX" ) )
return;
}
if ( strcmp( t, td->m_szType ) )
{
vprint( 0, "class %s has an incorrect FIELD_ type for variable '%s (%s, %s)'\n",
m_szName, var->m_szName, var->m_szType, td->m_szType );
}
}
bool CClass::CheckForMissingTypeDescriptionFields( int& missingcount, bool createtds )
{
bool bret = false;
missingcount = 0;
// Didn't specify a TYPEDESCRIPTION at all
if ( !m_bHasSaveRestoreData )
return bret;
for ( int i = 0; i < m_nVarCount; i++ )
{
CClassVariable *var = m_Variables[ i ];
bool isstatic = false;
char *p = var->m_szType;
while ( 1 )
{
p = CC_ParseToken( p );
if ( strlen( com_token ) <= 0 )
break;
if ( !stricmp( com_token, "static" ) )
{
isstatic = true;
break;
}
}
// Statics aren't encoded
if ( isstatic )
continue;
char *goodname = var->m_szName;
// Skip * pointer modifier
while ( *goodname && *goodname == '*' )
{
goodname++;
}
CTypeDescriptionField *td = FindTD( goodname );
if ( td )
{
ReportTypeMismatches( var, td );
continue;
}
bret = true;
missingcount++;
if ( !createtds )
{
vprint( 0, "class %s missing typedescription_t field for variable '%s %s'\n",
m_szName, var->m_szType, var->m_szName );
continue;
}
char const *t = TranslateSimpleType( var );
vprint( 0, "//\tClass %s:\n", m_szName );
if ( var->m_bIsArray &&
(
stricmp( var->m_szType, "char" ) ||
stricmp( t, "FIELD_STRING" )
) )
{
if ( *t )
{
vprint( 0, "\tDEFINE_ARRAY( %s, %s, %s ),\n", goodname, t, var->m_szArraySize );
}
else
{
vprint( 0, "\t// DEFINE_ARRAY( %s, %s, %s ),\n", goodname, var->m_szType, var->m_szArraySize );
}
}
else
{
if ( *t )
{
vprint( 0, "\tDEFINE_FIELD( %s, %s ),\n", goodname, t );
}
else
{
vprint( 0, "\t// DEFINE_FIELD( %s, %s ),\n", goodname, var->m_szType );
}
}
}
return bret;
}
bool CClass::CheckForPredictionFieldsInRecvTableNotMarkedAsSuchCorrectly( int &missingcount )
{
bool bret = false;
missingcount = 0;
// Didn't specify a TYPEDESCRIPTION at all
if ( !m_bHasPredictionData )
return bret;
if ( !m_bHasRecvTableData )
return bret;
for ( int i = 0; i < m_nVarCount; i++ )
{
CClassVariable *var = m_Variables[ i ];
bool inreceivetable = var->m_bInRecvTable;
bool isstatic = false;
char *p = var->m_szType;
while ( 1 )
{
p = CC_ParseToken( p );
if ( strlen( com_token ) <= 0 )
break;
if ( !stricmp( com_token, "static" ) )
{
isstatic = true;
break;
}
}
// Statics aren't encoded
if ( isstatic )
continue;
char *goodname = var->m_szName;
// Skip * pointer modifier
while ( *goodname && *goodname == '*' )
goodname++;
CTypeDescriptionField *td = FindPredTD( goodname );
// Missing variables are caught in a different routine
td = FindPredTD( goodname );
if ( !td )
continue;
// These are implicitly ok
if ( !strcmp( td->m_szDefineType, "DEFINE_PRED_TYPEDESCRIPTION" ) )
{
CClass *cl2 = processor->FindClass( td->m_szType );
if ( cl2 )
{
bret = cl2->CheckForPredictionFieldsInRecvTableNotMarkedAsSuchCorrectly( missingcount );
}
continue;
}
// Looks good (either in or out!)
// Check for appripriate flags
if ( inreceivetable == td->m_bRepresentedInRecvTable )
continue;
bret = true;
missingcount++;
if ( inreceivetable && !td->m_bRepresentedInRecvTable )
{
vprint( 0, "%s::%s: Missing FTYPEDESC_INSENDTABLE flag in prediction typedescription\n", m_szName, var->m_szName );
}
else
{
vprint( 0, "%s::%s: Field marked as FTYPEDESC_INSENDTABLE in prediction typedescription missing from RecvTable\n", m_szName, var->m_szName );
}
}
return bret;
}
bool CClass::CheckForMissingPredictionFields( int& missingcount, bool createtds )
{
bool bret = false;
missingcount = 0;
// Didn't specify a TYPEDESCRIPTION at all
if ( !m_bHasPredictionData )
return bret;
for ( int i = 0; i < m_nVarCount; i++ )
{
CClassVariable *var = m_Variables[ i ];
// private and protected variables can't be referenced in data tables right now
//if ( var->m_Type != CClassVariable::TPUBLIC )
// continue;
bool isstatic = false;
char *p = var->m_szType;
while ( 1 )
{
p = CC_ParseToken( p );
if ( strlen( com_token ) <= 0 )
break;
if ( !stricmp( com_token, "static" ) )
{
isstatic = true;
break;
}
}
// Statics aren't encoded
if ( !isstatic )
{
char *goodname = var->m_szName;
// Skip * pointer modifier
while ( *goodname && *goodname == '*' )
goodname++;
CTypeDescriptionField *td = FindPredTD( goodname );
td = FindPredTD( goodname );
if ( !td )
{
bret = true;
missingcount++;
if ( !createtds )
{
vprint( 0, "class %s missing prediction typedescription_t field for variable '%s %s'\n",
m_szName, var->m_szType, var->m_szName );
}
else
{
char const *t = TranslateSimpleType( var );
vprint( 0, "//\tClass %s:\n", m_szName );
if ( var->m_bIsArray &&
(
stricmp( var->m_szType, "char" ) ||
stricmp( t, "FIELD_STRING" )
) )
{
if ( *t )
{
vprint( 0, "\tDEFINE_ARRAY( %s, %s, %s ),\n", goodname, t, var->m_szArraySize );
}
else
{
vprint( 0, "\t// DEFINE_ARRAY( %s, %s, %s ),\n", goodname, var->m_szType, var->m_szArraySize );
}
}
else
{
if ( *t )
{
vprint( 0, "\tDEFINE_FIELD( %s, %s ),\n", goodname, t );
}
else
{
vprint( 0, "\t// DEFINE_FIELD( %s, %s ),\n", goodname, var->m_szType );
}
}
}
}
}
}
return bret;
}
void AppendType( const char *token, char *type )
{
strcat( type, token );
strcat( type, " " );
}
class MissingType
{
public:
CClass *owning_class;
CClassVariable *var;
};
#include "utldict.h"
CUtlDict< MissingType, unsigned short > missing_types;
bool IsMissingType( CClass *cl, CClassVariable *var )
{
unsigned short lookup;
lookup = missing_types.Find( var->m_szType );
if ( lookup != missing_types.InvalidIndex() )
return true;
MissingType t;
t.owning_class = cl;
t.var = var;
missing_types.Insert( var->m_szType, t );
return true;
}
void ReportMissingTypes( void )
{
int c = missing_types.Count();
for ( int i= 0; i < c; i++ )
{
MissingType *t = &missing_types[ i ];
if ( !t )
continue;
if ( !t->owning_class )
continue;
if ( !t->owning_class->m_bDerivedFromCBaseEntity )
continue;
if ( !t->var )
continue;
vprint( 0, "Can't compute size of %s %s %s\n",
t->owning_class->m_szName, t->var->m_szType, t->var->m_szName );
}
}
void ClearMissingTypes()
{
missing_types.Purge();
}
static int GetTypeSize( CClass *cl, CClassVariable *var )
{
int out = 0;
char *input = var->m_szType;
// Don't know how to handle templatized things yet
if ( strstr( input, "<" ) )
{
IsMissingType( cl, var );
return out;
}
if ( strstr( var->m_szName, "*" ) )
{
return sizeof( void * );
}
if ( strstr( input, "bool" ) )
{
return sizeof( bool );
}
else if ( strstr( input, "int64" ) )
{
return sizeof( __int64 );
}
else if ( strstr( input, "short" ) )
{
return sizeof( short );
}
else if ( strstr( input, "unsigned short" ) )
{
return sizeof( unsigned short );
}
else if ( strstr( input, "int" ) )
{
return sizeof( int );
}
else if ( strstr( input, "float" ) )
{
return sizeof( float );
}
else if ( strstr( input, "vec_t" ) )
{
return sizeof( float );
}
else if ( strstr( input, "Vector" ) || strstr( input, "QAngle" ) )
{
return 3 * sizeof( float );
}
else if ( strstr( input, "vec3_t" ) )
{
return 3 * sizeof( float );
}
else if ( strstr( input, "char" ) )
{
return sizeof( char );
}
else if ( strstr( input, "unsigned char" ) )
{
return sizeof( unsigned char );
}
else if ( strstr( input, "BYTE" ) )
{
return sizeof( char );
}
else if ( strstr( input, "byte" ) )
{
return sizeof( char );
}
else if ( !strcmp( input, "unsigned" ) )
{
return sizeof(unsigned int);
}
else if ( strstr( input, "long" ) )
{
return sizeof( int );
}
else if ( strstr( input, "color32" ) )
{
return sizeof( int );
}
// It's a pointer
else if ( strstr( input, "*" ) )
{
return sizeof( void * );
}
// Static data doesn't count
else if ( strstr( input, "static" ) )
{
return 0;
}
// Okay, see if it's a classname
CClass *base = processor->FindClass( input );
if ( base )
{
return base->m_nClassDataSize;
}
IsMissingType( cl, var );
return out;
}
void CClass::AddVariable( int protection, char *type, char *name, bool array, char *arraysize )
{
CClassVariable *var = AddVar( name );
if ( !var )
return;
strcpy( var->m_szType, type );
var->m_Type = (CClassVariable::VARTYPE)protection;
var->m_TypeSize = GetTypeSize( this, var );
m_nClassDataSize += var->m_TypeSize;
if ( array )
{
var->m_bIsArray = true;
strcpy( var->m_szArraySize, arraysize );
}
else
{
var->m_bIsArray = false;
}
}
//-----------------------------------------------------------------------------
// Parses information to determine the base class of this class
//-----------------------------------------------------------------------------
bool CClass::ParseBaseClass( char *&input )
{
if ( !strcmp( com_token, "DECLARE_CLASS" )
|| !strcmp( com_token, "DECLARE_CLASS_GAMEROOT" )
|| !strcmp( com_token, "DECLARE_CLASS_NOFRIEND" ) )
{
input = CC_ParseToken( input );
Assert( !strcmp( com_token, "(") );
input = CC_ParseToken( input );
do
{
input = CC_ParseToken( input );
} while( strcmp( com_token, ",") );
m_szTypedefBaseClass[0] = 0;
input = CC_ParseToken( input );
do
{
strcat( m_szTypedefBaseClass, com_token );
input = CC_ParseToken( input );
} while( strcmp( com_token, ")") );
return true;
}
else if ( !strcmp( com_token, "DECLARE_CLASS_NOBASE" ) )
{
input = CC_ParseToken( input );
Assert( !strcmp( com_token, "(") );
input = CC_DiscardUntilMatchingCharIncludingNesting( input, "()" );
return true;
}
return false;
}
//-----------------------------------------------------------------------------
// Parses networkvars
//-----------------------------------------------------------------------------
bool CClass::ParseNetworkVar( char *&input, int protection )
{
MemberVarParse_t var;
if ( !strcmp( com_token, "CNetworkVar" ) ||
!strcmp( com_token, "CNetworkVarForDerived" ) ||
!strcmp( com_token, "CNetworkVarEmbedded" ) )
{
input = CC_ParseToken( input );
Assert( !strcmp( com_token, "(") );
input = CC_ParseToken( input );
do
{
strcat( var.m_pType, com_token );
strcat( var.m_pType, " " );
input = CC_ParseToken( input );
} while( strcmp( com_token, ",") );
input = CC_ParseToken( input );
do
{
strcat( var.m_pName, com_token );
input = CC_ParseToken( input );
} while( strcmp( com_token, ")") );
AddVariable( protection, var.m_pType, var.m_pName, false );
return true;
}
if ( !strcmp( com_token, "CNetworkHandle" ) || !strcmp( com_token, "CNetworkHandleForDerived" ) )
{
input = CC_ParseToken( input );
Assert( !strcmp( com_token, "(") );
input = CC_ParseToken( input );
strcpy( var.m_pType, "CHandle<" );
do
{
strcat( var.m_pType, com_token );
strcat( var.m_pType, " " );
input = CC_ParseToken( input );
} while( strcmp( com_token, ",") );
strcat( var.m_pType, ">" );
input = CC_ParseToken( input );
do
{
strcat( var.m_pName, com_token );
input = CC_ParseToken( input );
} while( strcmp( com_token, ")") );
AddVariable( protection, "EHANDLE", var.m_pName, false );
return true;
}
if ( !strcmp( com_token, "CNetworkVector" ) ||
!strcmp( com_token, "CNetworkVectorForDerived" ) ||
!strcmp( com_token, "CNetworkQAngle" ) )
{
input = CC_ParseToken( input );
Assert( !strcmp( com_token, "(") );
input = CC_ParseToken( input );
do
{
strcat( var.m_pName, com_token );
input = CC_ParseToken( input );
} while( strcmp( com_token, ")") );
AddVariable( protection, "Vector", var.m_pName, false );
return true;
}
if ( !strcmp( com_token, "CNetworkColor32" ) )
{
input = CC_ParseToken( input );
Assert( !strcmp( com_token, "(") );
input = CC_ParseToken( input );
do
{
strcat( var.m_pName, com_token );
input = CC_ParseToken( input );
} while( strcmp( com_token, ")") );
AddVariable( protection, "color32", var.m_pName, false );
return true;
}
if ( !strcmp( com_token, "CNetworkString" ) )
{
input = CC_ParseToken( input );
Assert( !strcmp( com_token, "(") );
input = CC_ParseToken( input );
do
{
strcat( var.m_pName, com_token );
input = CC_ParseToken( input );
} while( strcmp( com_token, ",") );
input = CC_ParseToken( input );
do
{
strcat( var.m_pArraySize, com_token );
input = CC_ParseToken( input );
} while( strcmp( com_token, ")") );
AddVariable( protection, "char *", var.m_pName, true, var.m_pArraySize );
return true;
}
if ( !strcmp( com_token, "CNetworkArray" ) || !strcmp( com_token, "CNetworkArrayForDerived" ) )
{
input = CC_ParseToken( input );
Assert( !strcmp( com_token, "(") );
input = CC_ParseToken( input );
do
{
strcat( var.m_pType, com_token );
strcat( var.m_pType, " " );
input = CC_ParseToken( input );
} while( strcmp( com_token, ",") );
input = CC_ParseToken( input );
do
{
strcat( var.m_pName, com_token );
input = CC_ParseToken( input );
} while( strcmp( com_token, ",") );
input = CC_ParseToken( input );
do
{
strcat( var.m_pArraySize, com_token );
input = CC_ParseToken( input );
} while( strcmp( com_token, ")") );
AddVariable( protection, var.m_pType, var.m_pName, true, var.m_pArraySize );
return true;
}
return false;
}
//-----------------------------------------------------------------------------
// Parses a class member definition
//-----------------------------------------------------------------------------
bool CClass::ParseClassMember( char *&input, int protection )
{
MemberVarParse_t var;
bool isfunction = false;
bool wascomma = false;
bool skipvar = false;
if ( ParseNetworkVar( input, protection ) )
return true;
strcpy( var.m_pName, com_token );
if ( !stricmp( var.m_pName, "SHARED_CLASSNAME" ) )
{
input = CC_ParseToken( input );
if ( !stricmp( com_token, "(" ) )
{
char inside[ 256 ];
char *saveinput = input;
input = CC_DiscardUntilMatchingCharIncludingNesting( input, "()" );
int len = input - saveinput;
strncpy( inside, saveinput, len );
inside[ len ] =0;
strcat( var.m_pName, "(" );
strcat( var.m_pName, inside );
}
}
do
{
input = CC_ParseToken( input );
if ( strlen( com_token ) <= 0 )
break;
if ( !stricmp( com_token, "(" ) )
{
char *saveinput = input;
isfunction = true;
input = CC_DiscardUntilMatchingCharIncludingNesting( input, "()" );
// see if the function is being declared in line here
input = CC_ParseToken( input );
if ( !stricmp( com_token, "const" ) )
{
// Swallow const if we see it
input = CC_ParseToken( input );
}
if ( !stricmp( com_token, "{" ) )
{
input = CC_DiscardUntilMatchingCharIncludingNesting( input, "{}" );
}
// pure virtual function?
else if ( !stricmp( com_token, "=" ) )
{
char ch;
input = CC_RawParseChar( input, ";", &ch );
}
// this was a pointer to a base function
else if ( !stricmp( com_token, "(" ) )
{
char *end = input - 2;
input = saveinput;
char pfn[ 256 ];
int len = end - saveinput;
strncpy( pfn, input, len );
pfn[ len ] = 0;
do
{
input = CC_ParseToken( input );
if ( strlen( com_token ) <= 0 )
break;
if ( com_token[0] == '*' )
{
break;
}
} while ( 1 );
if ( com_token[0] == '*' )
{
// com_token is the variable name
sprintf( var.m_pType, "%s (%s)", var.m_pName, pfn );
strcpy( var.m_pName, com_token );
input = end + 1;
}
if ( *input == '(' )
input++;
input = CC_DiscardUntilMatchingCharIncludingNesting( input, "()" );
isfunction = false;
}
break;
}
else if ( !stricmp( com_token, "[" ) )
{
// It's an array
var.m_bArray = true;
char ch;
char *oldinput = input;
do
{
input = CC_RawParseChar( input, "]", &ch );
if ( *input && ( *input == '[' ) )
{
input++;
continue;
}
break;
} while ( 1 );
int len = input-oldinput - 1;
if ( len > 0 )
{
strncpy( var.m_pArraySize, oldinput, len );
}
var.m_pArraySize[ len ] = 0;
break;
}
else if ( !stricmp( com_token, ";" ) )
{
break;
}
else if ( !stricmp( com_token, ":" ) && !isfunction )
{
// Eliminate the length specification
input = CC_ParseToken( input );
continue;
}
else if ( !stricmp( com_token, "," ) )
{
wascomma = true;
break;
}
// It's a templatized var
else if (( com_token[ strlen( com_token ) - 1 ] == '<' ) && strcmp(var.m_pName, "operator") )
{
do
{
AppendType( var.m_pName, var.m_pType );
strcpy( var.m_pName, com_token );
input = CC_ParseToken( input );
if ( strlen( com_token ) <= 0 )
break;
}
while ( strcmp( com_token, ">" ) );
AppendType( var.m_pName, var.m_pType );
strcpy( var.m_pName, com_token );
}
else
{
if ( !stricmp( var.m_pName, "typedef" ) ||
!stricmp( var.m_pName, "enum" ) ||
!stricmp( var.m_pName, "friend" ) )
{
skipvar = true;
}
AppendType( var.m_pName, var.m_pType );
strcpy( var.m_pName, com_token );
continue;
}
} while ( 1 );
if ( strlen( var.m_pType ) >= 1 )
{
var.m_pType[ strlen( var.m_pType ) - 1 ] = 0;
}
if ( var.m_pType[0]==0 &&
( !strcmp( var.m_pName, "CUSTOM_SCHEDULES" ) ||
!strcmp( var.m_pName, "DEFINE_CUSTOM_SCHEDULE_PROVIDER" ) ||
!strcmp( var.m_pName, "DEFINE_CUSTOM_AI" ) ||
!strcmp( var.m_pName, "DECLARE_DATADESC" ) ||
!strcmp( var.m_pName, "DECLARE_EMBEDDED_DATADESC" ) ||
!strcmp( var.m_pName, "DECLARE_SERVERCLASS" ) ||
!strcmp( var.m_pName, "DECLARE_CLIENTCLASS" ) ||
!strcmp( var.m_pName, "DECLARE_ENTITY_PANEL" ) ||
!strcmp( var.m_pName, "DECLARE_MINIMAP_PANEL" ) ||
!strcmp( var.m_pName, "MANUALMODE_GETSET_PROP" ) ) )
{
return true;
}
if ( var.m_pType[0]==0 &&
( !strcmp( var.m_pName, "DECLARE_PREDICTABLE" ) ||
!strcmp( var.m_pName, "DECLARE_EMBEDDED_PREDDESC" ) ) )
{
m_bHasPredictionData = true;
return true;
}
/*
if ( var.m_pName[0] == '*' )
{
strcat( type, " *" );
char newname[ 256 ];
strcpy( newname, &var.m_pName[1] );
strcpy( var.m_pName, newname );
}
*/
if ( isfunction )
{
CClassMemberFunction *member = AddMember( var.m_pName );
if ( member )
{
strcpy( member->m_szType, var.m_pType );
member->m_Type = (CClassMemberFunction::MEMBERTYPE)protection;
}
}
else
{
// It's a variable
do
{
if ( !skipvar )
{
AddVariable( protection, var.m_pType, var.m_pName, var.m_bArray, var.m_pArraySize );
}
else if ( !stricmp( var.m_pName, "BaseClass" ) )
{
if ( !m_szTypedefBaseClass[0] )
{
char *p = var.m_pType;
p = CC_ParseToken( p );
p = CC_ParseToken( p );
strcpy( m_szTypedefBaseClass, com_token );
}
}
if ( !wascomma )
break;
input = CC_ParseToken( input );
if ( strlen( com_token ) <= 0 )
break;
// Remove length specifiers
if ( !stricmp( com_token, ":" ) )
{
input = CC_ParseToken( input );
input = CC_ParseToken( input );
}
if ( !stricmp( com_token, "," ) )
{
input = CC_ParseToken( input );
}
if ( !stricmp( com_token, ";" ) )
break;
strcpy( var.m_pName, com_token );
} while ( 1 );
}
return true;
}
//-----------------------------------------------------------------------------
// Parses a nested class definition
//-----------------------------------------------------------------------------
bool CClass::ParseNestedClass( char *&input )
{
if ( stricmp( com_token, "struct" ) && stricmp( com_token, "class" ) )
return false;
input = CC_ParseToken( input );
if ( strlen( com_token ) > 0 )
{
//vprint( depth, "class %s\n", com_token );
char decorated[ 256 ];
sprintf( decorated, "%s::%s", m_szName, com_token );
CClass *cl = processor->AddClass( decorated );
// Now see if there's a base class
input = CC_ParseToken( input );
if ( !stricmp( com_token, ":" ) )
{
// Parse out public and then classname an
input = CC_ParseToken( input );
if ( !stricmp( com_token, "public" ) )
{
input = CC_ParseToken( input );
if ( strlen( com_token ) > 0 )
{
cl->SetBaseClass( com_token );
do
{
input = CC_ParseToken( input );
} while ( strlen( com_token ) && stricmp( com_token, "{" ) );
if ( !stricmp( com_token, "{" ) )
{
input = cl->ParseClassDeclaration( input );
}
}
}
}
else if ( !stricmp( com_token, "{" ) )
{
input = cl->ParseClassDeclaration( input );
}
}
return true;
}
//-----------------------------------------------------------------------------
// Parses public/protected/private
//-----------------------------------------------------------------------------
bool CClass::ParseProtection( char *&input, int &protection )
{
if ( !stricmp( com_token, "public" ) )
{
protection = 0;
input = CC_ParseToken( input );
Assert( !stricmp( com_token, ":" ) );
return true;
}
else if ( !stricmp( com_token, "protected" ) )
{
protection = 1;
input = CC_ParseToken( input );
Assert( !stricmp( com_token, ":" ) );
return true;
}
else if ( !stricmp( com_token, "private" ) )
{
protection = 2;
input = CC_ParseToken( input );
Assert( !stricmp( com_token, ":" ) );
return true;
}
return false;
}
// parse until } found
// public:, private:, protected: set protection mode, private is initial default
// if token is not one of those, then parse and concatenate all tokens up to the first
// ; or (
//
char *CClass::ParseClassDeclaration( char *input )
{
int nestcount = 1;
// public = 0, protected = 1, private = 2;
int protection = 2;
do
{
input = CC_ParseToken( input );
if ( strlen( com_token ) <= 0 )
break;
if ( com_token[ 1 ] == 0 )
{
if ( com_token[ 0 ] == '{' )
{
nestcount++;
}
else if ( com_token[ 0 ] == '}' )
{
nestcount--;
}
}
if ( ParseProtection( input, protection ) )
continue;
if ( !stricmp( com_token, ";" ) )
continue;
if ( com_token[0] == '#' )
{
// swallow rest of line
input = CC_ParseUntilEndOfLine( input );
continue;
}
if ( ParseNestedClass( input ) )
continue;
if ( nestcount == 1 )
{
// See if we found a line that describes the base class
if ( ParseBaseClass( input ) )
continue;
ParseClassMember( input, protection );
}
} while ( nestcount != 0 && ( strlen( com_token ) >= 0 ) );
return input;
}
static bool ShouldHungarianCheck( char const *name )
{
if ( !Q_strncmp( name, "m_", 2 ) ||
!Q_strncmp( name, "g_", 2 ) ||
!Q_strncmp( name, "s_", 2 ) )
{
return true;
}
return false;
}
enum Required
{
NEVER = 0,
ALWAYS
};
struct Impermissible
{
char const *prefix;
char const *mustinclude;
int required; // if true, then must match to be permitted
};
static Impermissible g_Permissibles[] =
{
{ "fl", "float", ALWAYS },
{ "b", "bool", ALWAYS },
{ "n", "int", ALWAYS },
{ "isz", "string_t", ALWAYS },
{ "i", "float", NEVER },
{ "i", "bool", NEVER },
{ "i", "short", NEVER },
{ "i", "long", NEVER },
{ "ui", "int", ALWAYS },
{ "sz", "char", ALWAYS },
{ "ch", "char", ALWAYS },
{ "uch", "float", NEVER },
{ "uch", "int", NEVER },
{ "uch", "short", NEVER },
{ "uch", "long", NEVER },
{ "s", "short", ALWAYS },
{ "us", "short", ALWAYS },
{ "l", "long", ALWAYS },
{ "ul", "long", ALWAYS },
// { "f", "int", NEVER },
// { "f", "short", NEVER },
// { "f", "int", NEVER },
{ "a", "UtlVector", ALWAYS },
{ "h", "handle", ALWAYS },
{ "p", "*", ALWAYS },
};
void CClass::CheckForHungarianErrors( int& warnings )
{
int testcount = sizeof( g_Permissibles ) / sizeof( g_Permissibles[ 0 ] );
for ( int i = 0; i < m_nVarCount; i++ )
{
CClassVariable *var = m_Variables[ i ];
// Only check m_, s_, and g_ variables for now
if ( !ShouldHungarianCheck( var->m_szName ) )
{
continue;
}
bool isstatic = false;
char *p = var->m_szType;
while ( 1 )
{
p = CC_ParseToken( p );
if ( strlen( com_token ) <= 0 )
break;
if ( !stricmp( com_token, "static" ) )
{
isstatic = true;
break;
}
}
// Check for errors
for ( int j = 0; j < testcount; ++j )
{
Impermissible *tst = &g_Permissibles[ j ];
bool match = !Q_strncmp( var->m_szName + 2, tst->prefix, Q_strlen( tst->prefix ) ) ? true : false;
if ( !match )
continue;
// The first character after the prefix must be upper case or we skip...
int nextchar = 2 + Q_strlen( tst->prefix );
if ( !isupper( var->m_szName[ nextchar ] ) )
continue;
bool typeFound = Q_stristr( var->m_szType, tst->mustinclude ) ? true : false;
switch ( tst->required )
{
default:
case ALWAYS:
{
if ( !typeFound )
{
vprint( 1, "%s might have wrong type %s\n", var->m_szName, var->m_szType );
++warnings;
}
else
{
return;
}
}
break;
case NEVER:
{
if ( typeFound )
{
vprint( 1, "%s might have wrong type %s\n", var->m_szName, var->m_szType );
++warnings;
}
else
{
return;
}
}
break;
}
}
if ( !Q_strncmp( var->m_szName, "m_f", 3 ) &&
Q_strncmp( var->m_szName, "m_fl", 4 ) && isupper( var->m_szName[3] ) )
{
// If it's a "flag" and not a "float" type, it better be a bool or an int
if ( !Q_stristr( var->m_szType, "bool" ) &&
!Q_strstr( var->m_szType, "int" ) )
{
vprint( 1, "%s might have wrong type %s\n", var->m_szName, var->m_szType );
++warnings;
return;
}
}
}
}