//========= Copyright Valve Corporation, All rights reserved. ============// // // The expression operator class - scalar math calculator // for a good list of operators and simple functions, see: // \\fileserver\user\MarcS\boxweb\aliveDistLite\v4.2.0\doc\alive\functions.txt // (although we'll want to implement elerp as the standard 3x^2 - 2x^3 with rescale) // //============================================================================= #include "movieobjects/dmeexpressionoperator.h" #include "movieobjects_interfaces.h" #include "datamodel/dmelementfactoryhelper.h" #include "datamodel/dmattribute.h" #include "mathlib/noise.h" #include "mathlib/vector.h" #include // memdbgon must be the last include file in a .cpp file!!! #include "tier0/memdbgon.h" //----------------------------------------------------------------------------- // Parsing helper methods //----------------------------------------------------------------------------- bool ParseLiteral( const char *&expr, float &value ) { const char *startExpr = expr; value = ( float )strtod( startExpr, const_cast< char** >( &expr ) ); return ( startExpr != expr ); } bool ParseString( const char *&expr, const char *str ) { const char *startExpr = expr; while ( ( *expr == ' ' ) || ( *expr == '\t' ) ) expr++; // skip whitespace expr = StringAfterPrefix( expr, str ); if ( expr ) return true; expr = startExpr; return false; } bool ParseStringList( const char *&expr, const char **pOps, int &nOp ) { while ( nOp-- ) { if ( ParseString( expr, pOps[ nOp ] ) ) return true; } return false; } bool ParseStringList( const char *&expr, const CUtlVector< CUtlString > &strings, int &nOp ) { while ( nOp-- ) { if ( ParseString( expr, strings[ nOp ] ) ) return true; } return false; } int FindString( const CUtlVector< CUtlString > &strings, const char *str ) { uint sn = strings.Count(); for ( uint si = 0; si < sn; ++si ) { if ( !Q_strcmp( str, strings[ si ] ) ) return si; } return -1; } class ParseState_t { public: ParseState_t( const CUtlStack &stack, const char *expr ) : m_stacksize( stack.Count() ), m_startingExpr( expr ) {} void Reset( CUtlStack &stack, const char *&expr ) { Assert( m_stacksize <= stack.Count() ); stack.PopMultiple( stack.Count() - m_stacksize ); expr = m_startingExpr; } private: int m_stacksize; const char* m_startingExpr; }; void CExpressionCalculator::SetVariable( int nVariableIndex, float value ) { m_varValues[ nVariableIndex ] = value; } void CExpressionCalculator::SetVariable( const char *var, float value ) { int vi = FindString( m_varNames, var ); if ( vi >= 0 ) { m_varValues[ vi ] = value; } else { m_varNames.AddToTail( var ); m_varValues.AddToTail( value ); } } int CExpressionCalculator::FindVariableIndex( const char *var ) { return FindString( m_varNames, var ); } bool CExpressionCalculator::Evaluate( float &value ) { m_bIsBuildingArgumentList = false; m_stack.PopMultiple( m_stack.Count() ); const char *pExpr = m_expr.Get(); bool success = ParseExpr( pExpr ); if ( success && m_stack.Count() == 1 ) { value = m_stack.Top(); return true; } value = 0.0f; return false; } //----------------------------------------------------------------------------- // Builds a list of variable names from the expression //----------------------------------------------------------------------------- bool CExpressionCalculator::BuildVariableListFromExpression( ) { m_bIsBuildingArgumentList = true; m_stack.PopMultiple( m_stack.Count() ); const char *pExpr = m_expr.Get(); bool bSuccess = ParseExpr( pExpr ); m_bIsBuildingArgumentList = false; if ( !bSuccess || m_stack.Count() != 1 ) { m_varNames.RemoveAll(); return false; } return true; } //----------------------------------------------------------------------------- // Iterate over variables //----------------------------------------------------------------------------- int CExpressionCalculator::VariableCount() { return m_varNames.Count(); } const char *CExpressionCalculator::VariableName( int nIndex ) { return m_varNames[nIndex]; } bool CExpressionCalculator::ParseExpr( const char *&expr ) { return ( expr != NULL ) && ParseConditional( expr ); } bool CExpressionCalculator::ParseConditional( const char *&expr ) { ParseState_t ps0( m_stack, expr ); if ( !ParseOr( expr ) ) { ps0.Reset( m_stack, expr ); return false; // nothing matched } ParseState_t ps1( m_stack, expr ); if ( ParseString( expr, "?" ) && ParseExpr( expr ) && ParseString( expr, ":" ) && ParseExpr( expr ) ) { float f3 = m_stack.Top(); m_stack.Pop(); float f2 = m_stack.Top(); m_stack.Pop(); float f1 = m_stack.Top(); m_stack.Pop(); m_stack.Push( f1 != 0.0f ? f2 : f3 ); return true; // and matched } ps1.Reset( m_stack, expr ); return true; // equality (or lower) matched } bool CExpressionCalculator::ParseOr( const char *&expr ) { ParseState_t ps0( m_stack, expr ); if ( !ParseAnd( expr ) ) { ps0.Reset( m_stack, expr ); return false; // nothing matched } ParseState_t ps1( m_stack, expr ); if ( ParseString( expr, "||" ) && ParseOr( expr ) ) { float f2 = m_stack.Top(); m_stack.Pop(); float f1 = m_stack.Top(); m_stack.Pop(); m_stack.Push( ( f1 != 0.0f ) || ( f2 != 0.0f ) ? 1 : 0 ); return true; // and matched } ps1.Reset( m_stack, expr ); return true; // equality (or lower) matched } bool CExpressionCalculator::ParseAnd( const char *&expr ) { ParseState_t ps0( m_stack, expr ); if ( !ParseEquality( expr ) ) { ps0.Reset( m_stack, expr ); return false; // nothing matched } ParseState_t ps1( m_stack, expr ); if ( ParseString( expr, "&&" ) && ParseAnd( expr ) ) { float f2 = m_stack.Top(); m_stack.Pop(); float f1 = m_stack.Top(); m_stack.Pop(); m_stack.Push( ( f1 != 0.0f ) && ( f2 != 0.0f ) ? 1 : 0 ); return true; // and matched } ps1.Reset( m_stack, expr ); return true; // equality (or lower) matched } bool CExpressionCalculator::ParseEquality( const char *&expr ) { ParseState_t ps0( m_stack, expr ); if ( !ParseLessGreater( expr ) ) { ps0.Reset( m_stack, expr ); return false; // nothing matched } const char *pOps[] = { "==", "!=" }; int nOp = 2; ParseState_t ps1( m_stack, expr ); if ( ParseStringList( expr, pOps, nOp ) && ParseEquality( expr ) ) { float f2 = m_stack.Top(); m_stack.Pop(); float f1 = m_stack.Top(); m_stack.Pop(); switch ( nOp ) { case 0: // == m_stack.Push( f1 == f2 ? 1 : 0 ); break; case 1: // != m_stack.Push( f1 != f2 ? 1 : 0 ); break; } return true; // equality matched } ps1.Reset( m_stack, expr ); return true; // lessgreater (or lower) matched } bool CExpressionCalculator::ParseLessGreater( const char *&expr ) { ParseState_t ps0( m_stack, expr ); if ( !ParseAddSub( expr ) ) { ps0.Reset( m_stack, expr ); return false; // nothing matched } const char *pOps[] = { "<", ">", "<=", ">=" }; int nOp = 4; ParseState_t ps1( m_stack, expr ); if ( ParseStringList( expr, pOps, nOp ) && ParseLessGreater( expr ) ) { float f2 = m_stack.Top(); m_stack.Pop(); float f1 = m_stack.Top(); m_stack.Pop(); switch ( nOp ) { case 0: // < m_stack.Push( f1 < f2 ? 1 : 0 ); break; case 1: // > m_stack.Push( f1 > f2 ? 1 : 0 ); break; case 2: // <= m_stack.Push( f1 <= f2 ? 1 : 0 ); break; case 3: // >= m_stack.Push( f1 >= f2 ? 1 : 0 ); break; } return true; // inequality matched } ps1.Reset( m_stack, expr ); return true; // addsub (or lower) matched } bool CExpressionCalculator::ParseAddSub( const char *&expr ) { ParseState_t ps0( m_stack, expr ); if ( !ParseDivMul( expr ) ) { ps0.Reset( m_stack, expr ); return false; // nothing matched } const char *pOps[] = { "+", "-" }; int nOp = 2; ParseState_t ps1( m_stack, expr ); if ( ParseStringList( expr, pOps, nOp ) && ParseAddSub( expr ) ) { float f2 = m_stack.Top(); m_stack.Pop(); float f1 = m_stack.Top(); m_stack.Pop(); switch ( nOp ) { case 0: // + m_stack.Push( f1 + f2 ); break; case 1: // - m_stack.Push( f1 - f2 ); break; } return true; // addsub matched } ps1.Reset( m_stack, expr ); return true; // divmul (or lower) matched } bool CExpressionCalculator::ParseDivMul( const char *&expr ) { ParseState_t ps0( m_stack, expr ); if ( !ParseUnary( expr ) ) { ps0.Reset( m_stack, expr ); return false; // nothing matched } const char *pOps[] = { "*", "/", "%" }; int nOp = 3; ParseState_t ps1( m_stack, expr ); if ( ParseStringList( expr, pOps, nOp ) && ParseDivMul( expr ) ) { float f2 = m_stack.Top(); m_stack.Pop(); float f1 = m_stack.Top(); m_stack.Pop(); switch ( nOp ) { case 0: // * m_stack.Push( f1 * f2 ); break; case 1: // / m_stack.Push( f1 / f2 ); break; case 2: // % m_stack.Push( fmod( f1, f2 ) ); break; } return true; // divmul matched } ps1.Reset( m_stack, expr ); return true; // unary (or lower) matched } bool CExpressionCalculator::ParseUnary( const char *&expr ) { ParseState_t ps( m_stack, expr ); const char *pOps[] = { "+", "-", "!" }; int nOp = 3; if ( ParseStringList( expr, pOps, nOp ) && ParseUnary( expr ) ) { float f1 = m_stack.Top(); m_stack.Pop(); switch ( nOp ) { case 0: // + m_stack.Push( f1 ); break; case 1: // - m_stack.Push( -f1 ); break; case 2: // ! m_stack.Push( f1 == 0 ? 1 : 0 ); break; } return true; } ps.Reset( m_stack, expr ); if ( ParsePrimary( expr ) ) return true; ps.Reset( m_stack, expr ); return false; } bool CExpressionCalculator::ParsePrimary( const char *&expr ) { ParseState_t ps( m_stack, expr ); float value = 0.0f; if ( ParseLiteral( expr, value ) ) { m_stack.Push( value ); return true; } ps.Reset( m_stack, expr ); int nVar = m_varNames.Count(); if ( ParseStringList( expr, m_varNames, nVar) ) { m_stack.Push( m_varValues[ nVar ] ); return true; } ps.Reset( m_stack, expr ); if ( ParseString( expr, "(" ) && ParseExpr( expr ) && ParseString( expr, ")" ) ) { return true; } ps.Reset( m_stack, expr ); if ( Parse1ArgFunc( expr ) || Parse2ArgFunc( expr ) || Parse3ArgFunc( expr ) || // Parse4ArgFunc( expr ) || Parse5ArgFunc( expr ) ) { return true; } // If we're parsing it to discover names of variable names, add them here if ( !m_bIsBuildingArgumentList ) return false; // Variables can't start with a number if ( isdigit( *expr ) ) return false; const char *pStart = expr; while ( isalnum( *expr ) || *expr == '_' ) { ++expr; } int nLen = (size_t)expr - (size_t)pStart; char *pVariableName = (char*)_alloca( nLen+1 ); memcpy( pVariableName, pStart, nLen ); pVariableName[nLen] = 0; SetVariable( pVariableName, 0.0f ); m_stack.Push( 0.0f ); return true; } /* dtor(d) : converts degrees to radians rtod(r) : converts radians to degrees abs(a) : absolute value floor(a) : rounds down to the nearest integer ceiling(a) : rounds up to the nearest integer round(a) : rounds to the nearest integer sgn(a) : if a < 0 returns -1 else 1 sqr(a) : returns a * a sqrt(a) : returns sqrt(a) sin(a) : sin(a), a is in degrees asin(a) : asin(a) returns degrees cos(a) : cos(a), a is in degrees acos(a) : acos(a) returns degrees tan(a) : tan(a), a is in degrees exp(a) : returns the exponential function of a log(a) : returns the natural logaritm of a */ bool CExpressionCalculator::Parse1ArgFunc( const char *&expr ) { ParseState_t ps( m_stack, expr ); const char *pFuncs[] = { "abs", "sqr", "sqrt", "sin", "asin", "cos", "acos", "tan", "exp", "log", "dtor", "rtod", "floor", "ceiling", "round", "sign" }; int nFunc = 16; if ( ParseStringList( expr, pFuncs, nFunc ) && ParseString( expr, "(" ) && ParseExpr( expr ) && ParseString( expr, ")" ) ) { float f1 = m_stack.Top(); m_stack.Pop(); switch ( nFunc ) { case 0: // abs m_stack.Push( fabs( f1 ) ); break; case 1: // sqr m_stack.Push( f1 * f1 ); break; case 2: // sqrt m_stack.Push( sqrt( f1 ) ); break; case 3: // sin m_stack.Push( sin( f1 ) ); break; case 4: // asin m_stack.Push( asin( f1 ) ); break; case 5: // cos m_stack.Push( cos( f1 ) ); break; case 6: // acos m_stack.Push( acos( f1 ) ); break; case 7: // tan m_stack.Push( tan( f1 ) ); break; case 8: // exp m_stack.Push( exp( f1 ) ); break; case 9: // log m_stack.Push( log( f1 ) ); break; case 10: // dtor m_stack.Push( DEG2RAD( f1 ) ); break; case 11: // rtod m_stack.Push( RAD2DEG( f1 ) ); break; case 12: // floor m_stack.Push( floor( f1 ) ); break; case 13: // ceiling m_stack.Push( ceil( f1 ) ); break; case 14: // round m_stack.Push( floor( f1 + 0.5f ) ); break; case 15: // sign m_stack.Push( f1 >= 0.0f ? 1.0f : -1.0f ); break; } return true; } return false; } /* min(a,b) : if ab returns a else b atan2(a,b) : atan2(a/b) returns degrees pow(a,b) : function returns a raised to the power of b */ bool CExpressionCalculator::Parse2ArgFunc( const char *&expr ) { ParseState_t ps( m_stack, expr ); const char *pFuncs[] = { "min", "max", "atan2", "pow" }; int nFunc = 4; if ( ParseStringList( expr, pFuncs, nFunc ) && ParseString( expr, "(" ) && ParseExpr( expr ) && ParseString( expr, "," ) && ParseExpr( expr ) && ParseString( expr, ")" ) ) { float f2 = m_stack.Top(); m_stack.Pop(); float f1 = m_stack.Top(); m_stack.Pop(); switch ( nFunc ) { case 0: // min m_stack.Push( min( f1, f2 ) ); break; case 1: // max m_stack.Push( max( f1, f2 ) ); break; case 2: // atan2 m_stack.Push( atan2( f1, f2 ) ); break; case 3: // pow m_stack.Push( pow( f1, f2 ) ); break; } return true; } return false; } /* inrange(x,a,b) : if x is between a and b, returns 1 else returns 0 clamp(x,a,b) : see bound() above ramp(value,a,b) : returns 0 -> 1 as value goes from a to b lerp(factor,a,b) : returns a -> b as value goes from 0 to 1 cramp(value,a,b) : clamp(ramp(value,a,b),0,1) clerp(factor,a,b) : clamp(lerp(factor,a,b),a,b) elerp(x,a,b) : ramp( 3*x*x - 2*x*x*x, a, b) //elerp(factor,a,b) : lerp(lerp(sind(clerp(factor,-90,90)),0.5,1.0),a,b) noise(a,b,c) : { solid noise pattern (improved perlin noise) indexed with three numbers } */ float ramp( float x, float a, float b ) { return ( x - a ) / ( b - a ); } float lerp( float x, float a, float b ) { return a + x * ( b - a ); } float smoothstep( float x ) { return 3*x*x - 2*x*x*x; } bool CExpressionCalculator::Parse3ArgFunc( const char *&expr ) { ParseState_t ps( m_stack, expr ); const char *pFuncs[] = { "inrange", "clamp", "ramp", "lerp", "cramp", "clerp", "elerp", "noise" }; int nFunc = 8; if ( ParseStringList( expr, pFuncs, nFunc ) && ParseString( expr, "(" ) && ParseExpr( expr ) && ParseString( expr, "," ) && ParseExpr( expr ) && ParseString( expr, "," ) && ParseExpr( expr ) && ParseString( expr, ")" ) ) { float f3 = m_stack.Top(); m_stack.Pop(); float f2 = m_stack.Top(); m_stack.Pop(); float f1 = m_stack.Top(); m_stack.Pop(); switch ( nFunc ) { case 0: // inrange m_stack.Push( ( f1 >= f2 ) && ( f1 <= f3 ) ? 1.0f : 0.0f ); break; case 1: // clamp m_stack.Push( clamp( f1, f2, f3 ) ); break; case 2: // ramp m_stack.Push( ramp( f1, f2, f3 ) ); break; case 3: // lerp m_stack.Push( lerp( f1, f2, f3 ) ); break; case 4: // cramp m_stack.Push( clamp( ramp( f1, f2, f3 ), 0, 1 ) ); break; case 5: // clerp m_stack.Push( clamp( lerp( f1, f2, f3 ), f2, f3 ) ); break; case 6: // elerp m_stack.Push( lerp( smoothstep( f1 ), f2, f3 ) ); break; case 7: // noise m_stack.Push( ImprovedPerlinNoise( Vector( f1, f2, f3 ) ) ); break; } return true; } return false; } //bool CExpressionCalculator::Parse4ArgFunc( const char *&expr ); /* rescale (X,Xa,Xb,Ya,Yb) : lerp(ramp(X,Xa,Xb),Ya,Yb) crescale(X,Xa,Xb,Ya,Yb) : clamp(rescale(X,Xa,Xb,Ya,Yb),Ya,Yb) */ float rescale( float x, float a, float b, float c, float d ) { return lerp( ramp( x, a, b ), c, d ); } bool CExpressionCalculator::Parse5ArgFunc( const char *&expr ) { ParseState_t ps( m_stack, expr ); const char *pFuncs[] = { "rescale", "crescale" }; int nFunc = 2; if ( ParseStringList( expr, pFuncs, nFunc ) && ParseString( expr, "(" ) && ParseExpr( expr ) && ParseString( expr, "," ) && ParseExpr( expr ) && ParseString( expr, "," ) && ParseExpr( expr ) && ParseString( expr, "," ) && ParseExpr( expr ) && ParseString( expr, "," ) && ParseExpr( expr ) && ParseString( expr, ")" ) ) { float f5 = m_stack.Top(); m_stack.Pop(); float f4 = m_stack.Top(); m_stack.Pop(); float f3 = m_stack.Top(); m_stack.Pop(); float f2 = m_stack.Top(); m_stack.Pop(); float f1 = m_stack.Top(); m_stack.Pop(); switch ( nFunc ) { case 0: // rescale m_stack.Push( rescale( f1, f2, f3, f4, f5 ) ); break; case 1: // crescale m_stack.Push( clamp( rescale( f1, f2, f3, f4, f5 ), f4, f5 ) ); break; } return true; } return false; } void TestCalculator( const char *expr, float answer ) { CExpressionCalculator calc( expr ); float result = 0.0f; #ifdef DBGFLAG_ASSERT bool success = #endif calc.Evaluate( result ); Assert( success && ( result == answer ) ); } void TestCalculator( const char *expr, float answer, const char *var, float value ) { CExpressionCalculator calc( expr ); calc.SetVariable( var, value ); float result = 0.0f; #ifdef DBGFLAG_ASSERT bool success = #endif calc.Evaluate( result ); Assert( success && ( result == answer ) ); } void TestCalculator() { // TestCalculator( "-1", 1 ); TestCalculator( "2 * 3 + 4", 10 ); TestCalculator( "2 + 3 * 4", 14 ); TestCalculator( "2 * 3 * 4", 24 ); TestCalculator( "2 * -3 + 4", -2 ); TestCalculator( "12.0 / 2.0", 6 ); TestCalculator( "(2*3)+4", 10 ); TestCalculator( "( 1 + 2 ) / (1+2)", 1 ); TestCalculator( "(((5)))", 5 ); TestCalculator( "--5", 5 ); TestCalculator( "3.5 % 2", 1.5 ); TestCalculator( "1e-2", 0.01 ); TestCalculator( "9 == ( 3 * ( 1 + 2 ) )", 1 ); TestCalculator( "9 != ( 3 * ( 1 + 2 ) )", 0 ); TestCalculator( "9 <= ( 3 * ( 1 + 2 ) )", 1 ); TestCalculator( "9 < ( 3 * ( 1 + 2 ) )", 0 ); TestCalculator( "9 < 3", 0 ); TestCalculator( "10 >= 5", 1 ); // TestCalculator( "9 < ( 3 * ( 2 + 2 ) )", 0 ); TestCalculator( "x + 1", 5, "x", 4 ); TestCalculator( "pi - 3.14159", 0, "pi", 3.14159 ); // TestCalculator( "pi / 2", 0, "pi", 3.14159 ); TestCalculator( "abs(-10)", 10 ); TestCalculator( "sqr(-5)", 25 ); TestCalculator( "sqrt(9)", 3 ); // TestCalculator( "sqrt(-9)", -3 ); TestCalculator( "pow(2,3)", 8 ); TestCalculator( "min(abs(-4),2+3/2)", 3.5 ); TestCalculator( "round(0.5)", 1 ); TestCalculator( "round(0.49)", 0 ); TestCalculator( "round(-0.5)", 0 ); TestCalculator( "round(-0.51)", -1 ); TestCalculator( "inrange( 5, -8, 10 )", 1 ); TestCalculator( "inrange( 5, 5, 10 )", 1 ); TestCalculator( "inrange( 5, 6, 10 )", 0 ); TestCalculator( "elerp( 1/4, 0, 1 )", 3/16.0f - 1/32.0f ); TestCalculator( "rescale( 0.5, -1, 1, 0, 100 )", 75 ); TestCalculator( "1 > 2 ? 6 : 9", 9 ); TestCalculator( "1 ? 1 ? 2 : 4 : 1 ? 6 : 8", 2 ); TestCalculator( "0 ? 1 ? 2 : 4 : 1 ? 6 : 8", 6 ); TestCalculator( "noise( 0.123, 4.56, 78.9 )", ImprovedPerlinNoise( Vector( 0.123, 4.56, 78.9 ) ) ); } //----------------------------------------------------------------------------- // Expose this class to the scene database //----------------------------------------------------------------------------- IMPLEMENT_ELEMENT_FACTORY( DmeExpressionOperator, CDmeExpressionOperator ); //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- void CDmeExpressionOperator::OnConstruction() { m_result.Init( this, "result" ); m_expr.Init( this, "expr" ); m_bSpewResult.Init( this, "spewresult" ); #ifdef _DEBUG TestCalculator(); #endif _DEBUG } void CDmeExpressionOperator::OnDestruction() { } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- bool CDmeExpressionOperator::IsInputAttribute( CDmAttribute *pAttribute ) { const char *pName = pAttribute->GetName( ); #if 0 // skip this test, since none of these are float attributes, but leave the code as a reminder if ( Q_strcmp( pName, "name" ) == 0 ) return false; if ( Q_strcmp( pName, "expr" ) == 0 ) return false; #endif if ( Q_strcmp( pName, "result" ) == 0 ) return false; if ( pAttribute->GetType() != AT_FLOAT ) return false; return true; } void CDmeExpressionOperator::Operate() { CExpressionCalculator calc( m_expr.Get() ); for ( CDmAttribute *pAttribute = FirstAttribute(); pAttribute; pAttribute = pAttribute->NextAttribute() ) { if ( IsInputAttribute( pAttribute ) ) { const char *pName = pAttribute->GetName( ); calc.SetVariable( pName, pAttribute->GetValue< float >() ); } } float oldValue = m_result; calc.Evaluate( oldValue ); m_result = oldValue; if ( m_bSpewResult ) { Msg( "%s = '%f'\n", GetName(), (float)m_result ); } } void CDmeExpressionOperator::GetInputAttributes( CUtlVector< CDmAttribute * > &attrs ) { for ( CDmAttribute *pAttribute = FirstAttribute(); pAttribute; pAttribute = pAttribute->NextAttribute() ) { if ( IsInputAttribute( pAttribute ) ) { attrs.AddToTail( pAttribute ); } } attrs.AddToTail( m_expr.GetAttribute() ); } void CDmeExpressionOperator::GetOutputAttributes( CUtlVector< CDmAttribute * > &attrs ) { attrs.AddToTail( m_result.GetAttribute() ); } void CDmeExpressionOperator::SetSpewResult( bool state ) { m_bSpewResult = state; }