Some code restyling: VECTOR_PCB is an array. Cleanup uncontrolled definitions of abs, max, etc. max is now overloaded function and MAX is a macro.

3d-viewer/3d_draw.cpp

@@ -903,8 +903,8 @@ void D_PAD::Draw3D( EDA_3D_CANVAS* glcanvas )
     int     color;
 
     scale = g_Parm_3D_Visu.m_BoardScale;
-    holeX = (double) TO_LEGACY_LU_DBL( m_Drill.x ) * scale / 2;
-    holeY = (double) TO_LEGACY_LU_DBL( m_Drill.y ) * scale / 2;
+    holeX = (double) TO_LEGACY_LU_DBL( m_Drill.x() ) * scale / 2;
+    holeY = (double) TO_LEGACY_LU_DBL( m_Drill.y() ) * scale / 2;
     hole  = MIN( holeX, holeY );
 
     /* Calculate the center of the pad. */
@@ -914,8 +914,8 @@ void D_PAD::Draw3D( EDA_3D_CANVAS* glcanvas )
     xc  = ux0;
     yc  = uy0;
 
-    dx = dx0 = TO_LEGACY_LU( m_Size.x ) >> 1;
-    dy = dy0 = TO_LEGACY_LU( m_Size.y ) >> 1;
+    dx = dx0 = TO_LEGACY_LU( m_Size.x() ) >> 1;
+    dy = dy0 = TO_LEGACY_LU( m_Size.y() ) >> 1;
 
     angle  = m_Orient;
     drillx = m_Pos.x * scale;
@@ -980,13 +980,13 @@ void D_PAD::Draw3D( EDA_3D_CANVAS* glcanvas )
         {
             delta_cx = dx - dy;
             delta_cy = 0;
-            w = TO_LEGACY_LU( m_Size.y ) * scale;
+            w = TO_LEGACY_LU( m_Size.y() ) * scale;
         }
         else /* Vertical ellipse */
         {
             delta_cx = 0;
             delta_cy = dy - dx;
-            w = TO_LEGACY_LU( m_Size.x ) * scale;
+            w = TO_LEGACY_LU( m_Size.x() ) * scale;
         }
 
         RotatePoint( &delta_cx, &delta_cy, angle );

bitmap2component/bitmap2component.cpp

@@ -37,13 +37,6 @@
 #include "auxiliary.h"
 
 
-#ifndef max
-    #define max( a, b ) ( ( (a) > (b) ) ? (a) : (b) )
-#endif
-#ifndef min
-    #define min( a, b ) ( ( (a) < (b) ) ? (a) : (b) )
-#endif
-
 // Define some types used here from boost::polygon
 namespace bpl = boost::polygon;         // bpl = boost polygon library
 using namespace bpl::operators;         // +, -, =, ...
@@ -476,7 +469,7 @@ void BezierToPolyline( std::vector <potrace_dpoint_t>& aCornersBuffer,
      *  occur at an endpoint. */
     dd0     = sq( p1.x - 2 * p2.x + p3.x ) + sq( p1.y - 2 * p2.y + p3.y );
     dd1     = sq( p2.x - 2 * p3.x + p4.x ) + sq( p2.y - 2 * p3.y + p4.y );
-    dd      = 6 * sqrt( max( dd0, dd1 ) );
+    dd      = 6 * sqrt( fmax( dd0, dd1 ) );
     e2      = 8 * delta <= dd ? 8 * delta / dd : 1;
     epsilon = sqrt( e2 ); /* necessary interval size */
 

common/common.cpp

@@ -418,7 +418,7 @@ int ReturnValueFromString( EDA_UNITS_T aUnit, const wxString& TextValue, int Int
 
 const LENGTH_UNIT_DESC MillimetreDesc =
 {
-    LENGTH_UNITS<LENGTH_DEF>::millimetre(),
+    LENGTH_UNITS<LENGTH_PCB>::millimetre(),
     wxT( "mm" ),
     6
 };
@@ -426,7 +426,7 @@ const LENGTH_UNIT_DESC MillimetreDesc =
 
 const LENGTH_UNIT_DESC InchDesc =
 {
-    LENGTH_UNITS<LENGTH_DEF>::inch(),
+    LENGTH_UNITS<LENGTH_PCB>::inch(),
     wxT( "\"" ),
     7
 };
@@ -434,7 +434,7 @@ const LENGTH_UNIT_DESC InchDesc =
 
 const LENGTH_UNIT_DESC MilDesc =
 {
-    LENGTH_UNITS<LENGTH_DEF>::mil(),
+    LENGTH_UNITS<LENGTH_PCB>::mil(),
     wxT( "mil" ),
     5
 };
@@ -442,7 +442,7 @@ const LENGTH_UNIT_DESC MilDesc =
 
 const LENGTH_UNIT_DESC UnscaledDesc = /* stub */
 {
-    LENGTH_DEF::quantum(),
+    LENGTH_PCB::quantum(),
     wxT( "" ),
     4
 };
@@ -461,7 +461,7 @@ const LENGTH_UNIT_DESC *UnitDescription( EDA_UNITS_T aUnit ) {
 
 
 /* TODO: localisation */
-wxString LengthToString( const LENGTH_UNIT_DESC *aUnit, LENGTH_DEF aValue,
+wxString LengthToString( const LENGTH_UNIT_DESC *aUnit, LENGTH_PCB aValue,
                          bool aAdd_unit_symbol ) {
     wxString StringValue;
     double   value_to_print;
@@ -490,11 +490,11 @@ wxString LengthToString( const LENGTH_UNIT_DESC *aUnit, LENGTH_DEF aValue,
     return StringValue;
 }
 
-LENGTH_DEF StringToLength( const LENGTH_UNIT_DESC *aUnit, const wxString& TextValue )
+LENGTH_PCB StringToLength( const LENGTH_UNIT_DESC *aUnit, const wxString& TextValue )
 {
 
-    LENGTH_DEF    Value;
-    double dtmp = 0;
+    LENGTH_PCB  Value;
+    double      dtmp = 0;
 
     /* Acquire the 'right' decimal point separator */
     const struct lconv* lc = localeconv();
@@ -544,21 +544,21 @@ LENGTH_DEF StringToLength( const LENGTH_UNIT_DESC *aUnit, const wxString& TextVa
         aUnit = &MilDesc;
     }
 
-    Value = LENGTH_DEF( dtmp * LENGTH< double, 1 >( aUnit->m_Value ) );
+    Value = LENGTH_PCB( dtmp * LENGTH< double, 1 >( aUnit->m_Value ) );
 
     return Value;
 }
 
-void LengthToTextCtrl( wxTextCtrl& TextCtr, LENGTH_DEF Value )
+void LengthToTextCtrl( wxTextCtrl& TextCtr, LENGTH_PCB Value )
 {
     wxString msg = LengthToString( UnitDescription( g_UserUnit ), Value );
 
     TextCtr.SetValue( msg );
 }
 
-LENGTH_DEF LengthFromTextCtrl( const wxTextCtrl& TextCtr )
+LENGTH_PCB LengthFromTextCtrl( const wxTextCtrl& TextCtr )
 {
-    LENGTH_DEF value;
+    LENGTH_PCB value;
     wxString msg = TextCtr.GetValue();
 
     value = StringToLength( UnitDescription( g_UserUnit ), msg );

include/common.h

@@ -37,7 +37,7 @@
 
 
 #ifdef KICAD_NANOMETRE
-#include "length.h"
+#include "lengthpcb.h"
 #endif
 
 class wxAboutDialogInfo;
@@ -385,21 +385,21 @@ int ReturnValueFromTextCtrl( const wxTextCtrl& TextCtr, int Internal_Unit );
 
 struct LENGTH_UNIT_DESC
 {
-    LENGTH_DEF     m_Value;
-    const wxString m_Symbol;
-    int            m_Precision;
+    LENGTH_PCB       m_Value;
+    const wxString   m_Symbol;
+    int              m_Precision;
 };
 
 extern const LENGTH_UNIT_DESC MillimetreDesc, InchDesc, MilDesc;
 
 const LENGTH_UNIT_DESC *UnitDescription( EDA_UNITS_T aUnit );
 
-LENGTH_DEF       StringToLength( const LENGTH_UNIT_DESC *aUnit, const wxString& TextValue );
-wxString         LengthToString( const LENGTH_UNIT_DESC *aUnit, LENGTH_DEF aValue,
+LENGTH_PCB       StringToLength( const LENGTH_UNIT_DESC *aUnit, const wxString& TextValue );
+wxString         LengthToString( const LENGTH_UNIT_DESC *aUnit, LENGTH_PCB aValue,
                                  bool aAdd_unit_symbol = false );
 
-void             LengthToTextCtrl( wxTextCtrl& TextCtr, LENGTH_DEF Value );
-LENGTH_DEF       LengthFromTextCtrl( const wxTextCtrl& TextCtr );
+void             LengthToTextCtrl( wxTextCtrl& TextCtr, LENGTH_PCB Value );
+LENGTH_PCB       LengthFromTextCtrl( const wxTextCtrl& TextCtr );
 
 /* transition macros */
 #define STR_TO_LENGTH( unit, str, iu ) \

include/length.h

@@ -8,12 +8,9 @@
 #ifndef LENGTH_H_INCLUDED
 #define LENGTH_H_INCLUDED 1
 
-#include "limited_int.h"
+#include <math.h>
 
-/* type to be used by length units by default */
-typedef LIMITED_INT< int > DEF_LENGTH_VALUE;
-
-/**
+/*!
  * Length template class.
  * @param T actual type holding a value (be aware of precision and range!)
  * @param P power of length unit: 1 - length, 2 - area, 3 - volume, -1 - lin. density etc...
@@ -47,26 +44,34 @@ typedef LIMITED_INT< int > DEF_LENGTH_VALUE;
  *
  */
 
-template < typename T = DEF_LENGTH_VALUE, int P = 1 > class LENGTH;
+template < typename T = double, int P = 1 > class LENGTH;
 
-typedef LENGTH<DEF_LENGTH_VALUE, 1> LENGTH_DEF;
-
-/**
- * Length units contained in this class
+/*!
+ * Length units.
  */
 
 template <typename T> class LENGTH_UNITS;
 
-/**
- * For internal needs
+/*!
+ * The template that "inflate" LENGTH< T, 0 > class to T. Used with (*) and (/).
  */
 template < typename T, int P > struct LENGTH_TRAITS
 {
     typedef LENGTH<T, P> flat;
 };
 
+template < typename T > struct LENGTH_TRAITS< T, 0 >
+{
+    /* length dimension to power 0 is just a number, so LENGTH<T, 0> should be automatically converted to T */
+    typedef T flat;
+};
+
+/*!
+ * The template for value type conversions
+ */
 template < typename T > struct LENGTH_CASTS
 {
+     /*! This function to convert length value to given type T. */
      template< typename X > static T cast( const X x )
      {
          return T( x );
@@ -89,6 +94,9 @@ template <> struct LENGTH_CASTS < long >
      }
 };
 
+/** Forward declaration for LIMITED_INT to use with casts. */
+template < typename T > class LIMITED_INT;
+
 template < typename T > struct LENGTH_CASTS < LIMITED_INT< T > >
 {
      static LIMITED_INT< T > cast( const double x )
@@ -97,12 +105,6 @@ template < typename T > struct LENGTH_CASTS < LIMITED_INT< T > >
      }
 };
 
-template < typename T > struct LENGTH_TRAITS< T, 0 >
-{
-    /* length dimension to power 0 is just a number, so LENGTH<T, 0> should be automatically converted to T */
-    typedef T flat;
-};
-
 template< typename T, int P > class LENGTH
 {
     friend class LENGTH_UNITS< T >;
@@ -110,29 +112,36 @@ template< typename T, int P > class LENGTH
     template < typename Y, int R > friend class LENGTH;
 protected:
 
-    T m_U;
-    LENGTH( T units ) : m_U( units )
+    T u;
+    
+    LENGTH( T units ) : u( units )
     {
     }
+    
     static T RawValue( const LENGTH<T, P> &x )
     {
-        return x.m_U;
+        return x.u;
     }
+    
     static T RawValue( const T& x )
     {
         return x;
     }
+    
 public:
     typedef T value_type;
+    
     enum
     {
         dimension = P
     };
+    
     template< typename U > LENGTH( const LENGTH< U, P > &orig )
-    : m_U( LENGTH_CASTS < T >::cast( orig.m_U ) )
+    : u( LENGTH_CASTS < T >::cast( orig.u ) )
     {
     }
-    LENGTH( void ) : m_U()
+    
+    LENGTH( void ) : u()
     {
     }
     
@@ -149,134 +158,181 @@ public:
 
     LENGTH<T, P> & operator = ( const LENGTH<T, P> & y )
     {
-        this->m_U = y.m_U;
+        this->u = y.u;
         return *this;
     }
+    
     template< typename Y > operator LENGTH< Y, P > ( void )
     {
-        return LENGTH< Y, P >( this->m_U );
+        return LENGTH< Y, P >( this->u );
     }
+    
     /*************************/
     /* comparisons and tests */
     /*************************/
     bool operator ==( const LENGTH < T, P > y ) const
     {
-        return m_U == y.m_U;
+        return u == y.u;
     }
+    
     bool operator !=( const LENGTH < T, P > y ) const
     {
-        return m_U != y.m_U;
+        return u != y.u;
     }
+    
     bool operator <( const LENGTH < T, P > y ) const
     {
-        return m_U < y.m_U;
+        return u < y.u;
     }
+    
     bool operator >=( const LENGTH < T, P > y ) const
     {
-        return m_U >= y.m_U;
+        return u >= y.u;
     }
+    
     bool operator >( const LENGTH < T, P > y ) const
     {
-        return m_U > y.m_U;
+        return u > y.u;
     }
+    
     bool operator <=( const LENGTH < T, P > y ) const
     {
-        return m_U <= y.m_U;
+        return u <= y.u;
     }
+    
     bool operator !( void ) const
     {
-        return !m_U;
+        return !u;
     }
+    
     /*************************/
     /* basic arithmetic      */
     /*************************/
     LENGTH< T, P > operator - ( void ) const
     {
-        return LENGTH<T, P>(-this->m_U);
+        LENGTH< T, P > z;
+        z.u = -u;
+        return z;
     }
-    LENGTH< T, P > operator - ( const LENGTH< T, P > y ) const
+    
+    LENGTH< T, P >& operator -= ( const LENGTH< T, P > y )
     {
-        return m_U - y.m_U;
+        u -= y.u;
+        return *this;
     }
-    LENGTH< T, P > operator + ( const LENGTH< T, P > y ) const
+
+    friend LENGTH< T, P > operator - ( const LENGTH< T, P > x, const LENGTH< T, P > y )
     {
-        return m_U + y.m_U;
+        LENGTH< T, P > z = x;
+        z -= y;
+        return z;
     }
+    
+    LENGTH< T, P >& operator += ( const LENGTH< T, P > y )
+    {
+        u += y.u;
+        return *this;
+    }
+
+    friend LENGTH< T, P > operator + ( const LENGTH< T, P > x, const LENGTH< T, P > y )
+    {
+        LENGTH< T, P > z = x;
+	z += y;
+        return z;
+    }
+    
+    LENGTH< T, P >& operator *= ( const T y )
+    {
+        u *= y;
+        return *this;
+    }
+
+    LENGTH< T, P > operator * ( const T & y) const
+    {
+        LENGTH< T, P > z = *this;
+        z *= y;
+        return z;
+    }
+
     template < int R >
     typename LENGTH_TRAITS< T, P + R >::flat operator * ( const LENGTH<T, R> &y ) const
     {
-        return m_U * y.m_U;
-    }
-    LENGTH< T, P > operator * ( const T & y) const
-    {
-        return m_U * y;
-    }
-    LENGTH< T, P > friend operator * ( const T &y, const LENGTH<T, P> &x )
-    {
-        return x.m_U * y;
+        LENGTH< T, P > z;
+        z.u = u * y.u;
+        return z;
     }
     
+    LENGTH< T, P > friend operator * ( const T &y, const LENGTH<T, P> &x )
+    {
+        return x.u * y;
+    }
+    
+    LENGTH< T, P >& operator /= ( const T y )
+    {
+        u /= y;
+        return *this;
+    }
+    
+    LENGTH< T, P > operator / ( const T &y ) const
+    {
+        return u / y;
+    }
+
     template < int R >
     typename LENGTH_TRAITS< T, P - R >::flat operator / ( const LENGTH<T, R> &y ) const
     {
-        return m_U / y.m_U;
-    }
-    LENGTH< T, P > operator / ( const T &y ) const
-    {
-        return m_U / y;
-    }
-    LENGTH< T, -P > friend operator / ( const T &y, const LENGTH< T, P > &x )
-    {
-        return y / x.m_U;
-    }
-
-    /*************************/
-    /* assignment arithmetic */
-    /*************************/
-    LENGTH< T, P >& operator -= ( const LENGTH< T, P > y )
-    {
-        m_U -= y.m_U;
-        return *this;
-    }
-    LENGTH< T, P >& operator += ( const LENGTH< T, P > y )
-    {
-        m_U += y.m_U;
-        return *this;
-    }
-    LENGTH< T, P >& operator *= ( const T y )
-    {
-        m_U *= y;
-        return *this;
-    }
-    LENGTH< T, P >& operator /= ( const T y )
-    {
-        m_U /= y;
-        return *this;
+        return u / y.u;
     }
     
-    /*************************/
-    /* more functions        */
-    /*************************/
+    LENGTH< T, -P > friend operator / ( const T &y, const LENGTH< T, P > &x )
+    {
+        return y / x.u;
+    }
+
+    /******************************/
+    /* algebraic functions        */
+    /******************************/
+    friend LENGTH< T, P > abs( LENGTH< T, P > y )
+    {
+        return 0 < y.u? y : -y;
+    }
+    
+    friend LENGTH< T, P > max( LENGTH< T, P > x, LENGTH< T, P > y )
+    {
+        LENGTH< T, P > z;
+        z.u = hypot( x.u, y.u );
+        return z;
+    }
+
     friend LENGTH< T, P > sqrt( LENGTH< T, P*2 > y )
     {
-        return sqrt( y.m_U );
+        LENGTH< T, P > z;
+        z.u = sqrt( y.u );
+        return z;
     }
+    
     friend LENGTH< T, P > cbrt( LENGTH< T, P*3 > y )
     {
-        return cbrt( y.m_U );
+        LENGTH< T, P > z;
+        z.u = cbrt( y.u );
+        return z;
     }
+    
     friend LENGTH< T, P > hypot( LENGTH< T, P > x, LENGTH< T, P > y )
     {
-        return hypot( x.m_U, y.m_U );
+        LENGTH< T, P > z;
+        z.u = hypot( x.u, y.u );
+        return z;
     }
+    
     friend double atan2( LENGTH< T, P > x, LENGTH< T, P > y )
     {
-        return atan2( double ( x.m_U ), double( y.m_U ) );
+        return atan2( double ( x.u ), double( y.u ) );
     }
 
 };
 
-/**
+/*!
  * Units of length
  *
  * How to use them:
@@ -293,43 +349,61 @@ public:
  * is going to use relative units.
  */
 
-template < typename T = DEF_LENGTH_VALUE > class LENGTH_UNITS {
+template < typename T > class LENGTH_UNITS {
 protected:
     enum
     {
-        METRE = 1000000000, /* The ONLY constant connecting length to the real world */
+        METRE = 1000000000, /*!< The ONLY constant connecting length to the real world */
         
         INCH = METRE / 10000 * 254
     };
-    public:
-    static LENGTH< T, 1 > metre( void ) {
+    
+public:
+    /*! One metre. */
+    static LENGTH< T, 1 > metre( void ) 
+    {
         return T( METRE );
     }
-    static LENGTH< T, 1 > decimetre( void ) {
+    
+    /*! One decimetre. */
+    static LENGTH< T, 1 > decimetre( void ) 
+    {
         return T( METRE / 10 );
     }
-    static LENGTH< T, 1 > centimetre( void ) {
+    
+    static LENGTH< T, 1 > centimetre( void ) 
+    {
         return T( METRE / 100 );
     }
-    static LENGTH< T, 1 > millimetre( void ) {
+    
+    static LENGTH< T, 1 > millimetre( void ) 
+    {
         return T( METRE / 1000 );
     }
-    static LENGTH< T, 1 > micrometre( void ) {
+    
+    static LENGTH< T, 1 > micrometre( void ) 
+    {
         return T( METRE / 1000000 );
     }
-    static LENGTH< T, 1 > foot( void ) { /* do not think this will ever need */
+    
+    static LENGTH< T, 1 > foot( void ) 
+    {
         return T( INCH * 12 );
     }
-    static LENGTH< T, 1 > inch( void ) {
+    
+    static LENGTH< T, 1 > inch( void ) 
+    {
         return T( INCH );
     }
-    static LENGTH< T, 1 > mil( void ) {
+    
+    static LENGTH< T, 1 > mil( void ) 
+    {
         return T( INCH / 1000 );
     }
 };
 
 /**
-  * shortcut to get units of given length type
+  * Shortcut to get units of given length type
   */
 template < typename T, int D > class LENGTH_UNITS< LENGTH< T, D > >: public LENGTH_UNITS< T >
 {

include/lengthpcb.h

@@ -8,6 +8,7 @@
 
 #ifdef KICAD_NANOMETRE
 #include "length.h"
+#include "limited_int.h"
 
 /* switched type! */
 typedef LENGTH< LIMITED_INT< int >, 1 > LENGTH_PCB;
@@ -82,53 +83,126 @@ typedef double LENGTH_PCB_DBL;
 
 
 /// @TODO: nice template and refiling for it
-struct VECTOR_PCB
+class VECTOR_PCB
 {
-    LENGTH_PCB x, y;
-    VECTOR_PCB()
+public:
+    LENGTH_PCB data[2];
+
+    /** A vector from pair of coords. Constructor is avoided in favor to POD.
+     */
+    static VECTOR_PCB fromXY( LENGTH_PCB x, LENGTH_PCB y )
     {
+        VECTOR_PCB z = { x, y };
+        return z;
     }
-    VECTOR_PCB( LENGTH_PCB ax, LENGTH_PCB ay ): x( ax ), y( ay )
+    
+    LENGTH_PCB &operator[]( int i )
     {
+        return data[i];
     }
-    bool operator == ( const VECTOR_PCB &a ) const {
-        return x == a.x && y == a.y;
+
+    const LENGTH_PCB &operator[]( int i ) const
+    {
+        return data[i];
     }
-    bool operator != ( const VECTOR_PCB &a ) const {
-        return x != a.x || y != a.y;
+    
+    LENGTH_PCB & x()
+    {
+        return data[0];
     }
-    VECTOR_PCB & operator = (const VECTOR_PCB &a ) {
-        x = a.x;
-        y = a.y;
+
+    const LENGTH_PCB & x() const
+    {
+        return data[0];
+    }
+    
+    LENGTH_PCB & y()
+    {
+        return data[1];
+    }
+
+    const LENGTH_PCB & y() const
+    {
+        return data[1];
+    }
+
+    //LENGTH_PCB x, y;
+    bool operator == ( const VECTOR_PCB &b ) const
+    {
+        return data[0] == b.data[0] && data[1] == b.data[1];
+    }
+    
+    bool operator != ( const VECTOR_PCB &b ) const
+    {
+        return !(*this == b);
+    }
+    
+    VECTOR_PCB & operator -= ( const VECTOR_PCB &b )
+    {
+        data[0] -= b.data[0];
+        data[1] -= b.data[1];
         return *this;
     }
-    VECTOR_PCB & operator += (const VECTOR_PCB &a ) {
-        x += a.x;
-        y += a.y;
+    
+    VECTOR_PCB operator - ( const VECTOR_PCB &b ) const
+    {
+        VECTOR_PCB z = *this;
+        z -= b;
+        return z;
+    }
+    
+    VECTOR_PCB & operator += ( const VECTOR_PCB &b )
+    {
+        data[0] += b.data[0];
+        data[1] += b.data[1];
         return *this;
     }
-    VECTOR_PCB & operator -= (const VECTOR_PCB &a ) {
-        x -= a.x;
-        y -= a.y;
+    
+    VECTOR_PCB operator + ( VECTOR_PCB b ) const
+    {
+        VECTOR_PCB z = *this;
+        z += b;
+        return z;
+    }
+    
+    VECTOR_PCB & operator *= ( int b )
+    {
+        data[0] *= b;
+        data[1] *= b;
         return *this;
     }
-    VECTOR_PCB operator + (VECTOR_PCB add) const {
-        return VECTOR_PCB(x + add.x, y + add.y);
+    
+    VECTOR_PCB operator * ( int b ) const
+    {
+        VECTOR_PCB z = *this;
+        z *= b;
+        return z;
     }
-    VECTOR_PCB operator - (VECTOR_PCB add) const {
-        return VECTOR_PCB(x - add.x, y - add.y);
+    
+    VECTOR_PCB & operator /= ( int b )
+    {
+        data[0] /= b;
+        data[1] /= b;
+        return *this;
     }
-    VECTOR_PCB operator * (int factor) const {
-        return VECTOR_PCB(x * factor, y * factor);
-    }
-    VECTOR_PCB operator / (int factor) const {
-        return VECTOR_PCB(x / factor, y / factor);
+    
+    VECTOR_PCB operator / ( int b ) const
+    {
+        VECTOR_PCB z = *this;
+        z /= b;
+        return z;
     }
 };
 
-#define TO_LEGACY_LU_WXP( p ) ( wxPoint( TO_LEGACY_LU( ( p ).x ), TO_LEGACY_LU( ( p ).y ) ) )
-#define TO_LEGACY_LU_WXS( p ) ( wxSize( TO_LEGACY_LU( ( p ).x ), TO_LEGACY_LU( ( p ).y ) ) )
-#define FROM_LEGACY_LU_VEC( p ) ( VECTOR_PCB( FROM_LEGACY_LU( ( p ).x ), FROM_LEGACY_LU( ( p ).y ) ) )
+#define TO_LEGACY_LU_WXP( p ) ( wxPoint( \
+    TO_LEGACY_LU( ( p )[0] ), \
+    TO_LEGACY_LU( ( p )[1] ) ) )
+#define TO_LEGACY_LU_WXS( p ) ( wxSize( \
+    TO_LEGACY_LU( ( p )[0] ), \
+    TO_LEGACY_LU( ( p )[1] ) ) )
+#define FROM_LEGACY_LU_VEC( p ) ( VECTOR_PCB::fromXY( \
+    FROM_LEGACY_LU( ( p ).x ), \
+    FROM_LEGACY_LU( ( p ).y ) ) )
 
 
 #endif /* def LENGTHPCB_H_INCLUDED */

include/limited_int.h

@@ -15,21 +15,25 @@
 template < typename T = int > class LIMITED_INT {
 private:
     T m_Value;
+    
 public:
     LIMITED_INT( void ) : m_Value() {
     }
+    
     template<typename V> LIMITED_INT( const LIMITED_INT< V >& orig )
     :  m_Value( orig.m_Value )
     {
         assert(std::numeric_limits<T>::min() <= orig.m_Value);
         assert(orig.m_Value <= std::numeric_limits<T>::max());
     }
+    
     template<typename V> LIMITED_INT( const double v )
     :  m_Value( floor(v+0.5) )
     {
         assert(std::numeric_limits<T>::min() <= v);
         assert(v <= std::numeric_limits<T>::max());
     }
+    
     LIMITED_INT( T v ): m_Value( v )
     {
     }
@@ -38,6 +42,7 @@ public:
     {
         return m_Value;
     }
+    
     operator double( void ) const
     {
         return ( double )m_Value;
@@ -48,11 +53,13 @@ public:
         m_Value = src.m_Value;
         return *this;
     }
+    
     LIMITED_INT<T> & operator = ( T src )
     {
         m_Value = src;
         return *this;
     }
+    
     /*************************/
     /* comparisons and tests */
     /*************************/
@@ -64,10 +71,12 @@ public:
     {
         return m_Value == y.m_Value;
     }
+    
     bool operator == ( const T y ) const
     {
         return m_Value == y;
     }
+    
     friend bool operator == ( const T x, const LIMITED_INT< T > &y )
     {
         return x == y.m_Value;
@@ -77,10 +86,12 @@ public:
     {
         return m_Value != y.m_Value;
     }
+    
     bool operator != ( const T y ) const
     {
         return m_Value != y;
     }
+    
     friend bool operator != ( const T x, const LIMITED_INT< T > &y )
     {
         return x != y.m_Value;
@@ -90,10 +101,12 @@ public:
     {
         return m_Value < y.m_Value;
     }
+    
     bool operator < ( const T y ) const
     {
         return m_Value < y;
     }
+    
     friend bool operator < ( const T x, const LIMITED_INT< T > &y )
     {
         return x < y.m_Value;
@@ -103,10 +116,12 @@ public:
     {
         return m_Value >= y.m_Value;
     }
+    
     bool operator >= ( const T y ) const
     {
         return m_Value >= y;
     }
+    
     friend bool operator >= ( const T x, const LIMITED_INT<T> &y )
     {
         return x >= y.m_Value;
@@ -116,10 +131,12 @@ public:
     {
         return m_Value > y.m_Value;
     }
+    
     bool operator > ( const T y ) const
     {
         return m_Value > y;
     }
+    
     friend bool operator > ( const T x, const LIMITED_INT< T > &y )
     {
         return x > y.m_Value;
@@ -129,10 +146,12 @@ public:
     {
         return m_Value <= y.m_Value;
     }
+    
     bool operator <= ( const T y ) const
     {
         return m_Value <= y;
     }
+    
     friend bool operator <= ( const T x, const LIMITED_INT< T > &y )
     {
         return x <= y.m_Value;
@@ -147,18 +166,22 @@ public:
         assert( !( m_Value < 0 ) || std::numeric_limits< T >::min() - m_Value <= y.m_Value );
         return m_Value + y.m_Value;
     }
+    
     LIMITED_INT< T > operator + ( const T y ) const
     {
         return *this + LIMITED_INT< T >( y );
     }
+    
     friend LIMITED_INT< T > operator + ( const T x, const LIMITED_INT< T > &y )
     {
         return LIMITED_INT< T >( x ) + y;
     }
+    
     double operator + ( const double y ) const
     {
         return double( m_Value ) + y;
     }
+    
     friend double operator + ( const double x, const LIMITED_INT< T > &y )
     {
         return x + double( y.m_Value );
@@ -169,24 +192,29 @@ public:
         assert( -std::numeric_limits< T >::max() <= m_Value );
         return -m_Value;
     }
+    
     LIMITED_INT< T > operator - ( const LIMITED_INT< T > &y ) const
     {
         assert( !( 0 < m_Value ) || m_Value - std::numeric_limits< T >::max() <= y.m_Value );
         assert( !( m_Value < 0 ) || y.m_Value <= m_Value - std::numeric_limits< T >::min() );
         return m_Value - y.m_Value;
     }
+    
     LIMITED_INT< T > operator - ( const T y ) const
     {
         return *this - LIMITED_INT< T >( y );
     }
+    
     friend LIMITED_INT< T > operator - ( const T x, const LIMITED_INT< T > &y )
     {
         return LIMITED_INT< T >( x ) - y;
     }
+    
     double operator - ( const double y ) const
     {
         return double( m_Value ) - y;
     }
+    
     friend double operator - ( const double x, const LIMITED_INT< T > &y )
     {
         return x - double( y.m_Value );
@@ -204,18 +232,22 @@ public:
         || std::numeric_limits<T>::max() / m_Value <= y.m_Value );
         return m_Value * y.m_Value;
     }
+    
     LIMITED_INT<T> operator * ( const T y) const
     {
         return *this * LIMITED_INT< T >( y );
     }
+    
     friend LIMITED_INT< T > operator *( const T x, const LIMITED_INT< T > &y )
     {
         return LIMITED_INT< T >( x ) * y;
     }
+    
     double operator * ( const double y ) const
     {
         return double( m_Value ) * y;
     }
+    
     friend double operator * ( const double x, const LIMITED_INT< T > &y )
     {
         return x * double( y.m_Value );
@@ -227,18 +259,22 @@ public:
         || -std::numeric_limits< T >::max() <= m_Value );
         return m_Value / y.m_Value;
     }
+    
     LIMITED_INT<T> operator / ( const T y ) const
     {
         return *this / LIMITED_INT<T>(y);
     }
+    
     friend LIMITED_INT< T > operator / ( const T x, const LIMITED_INT< T > &y )
     {
         return LIMITED_INT< T >( x ) / y;
     }
+    
     double operator / ( const double y ) const
     {
         return double( m_Value ) / y;
     }
+    
     friend double operator / ( const double x, const LIMITED_INT< T > &y )
     {
         return x / double( y.m_Value );
@@ -248,62 +284,71 @@ public:
     {
         return m_Value % y.m_Value;
     }
+    
     LIMITED_INT<T> operator % ( const T y ) const
     {
         return *this % LIMITED_INT<T>(y);
     }
+    
     friend LIMITED_INT< T > operator % ( const T x, const LIMITED_INT< T > &y )
     {
         return LIMITED_INT< T >( x ) % y;
     }
-    /*************************/
-    /* assignment arithmetic */
-    /*************************/
+    
     LIMITED_INT< T >& operator += ( const LIMITED_INT< T > &y )
     {
         *this = *this + y;
         return *this;
     }
+    
     LIMITED_INT< T >& operator += ( const T y )
     {
         *this = *this + y;
         return *this;
     }
+    
     LIMITED_INT< T >& operator ++ ( void )
     {
         *this = *this + 1;
         return *this;
     }
+    
     LIMITED_INT< T >& operator -= ( const LIMITED_INT< T > &y )
     {
         *this = *this - y;
         return *this;
     }
+    
     LIMITED_INT< T >& operator -= ( const T y )
     {
         *this = *this - y;
         return *this;
     }
+    
     LIMITED_INT< T >& operator -- ( void )
     {
         *this = *this - 1;
         return *this;
     }
+    
     LIMITED_INT< T >& operator *= ( const LIMITED_INT< T > &y )
     {
         *this = *this * y;
         return *this;
     }
+    
     LIMITED_INT< T >& operator *= ( const T y )
     {
         *this = *this * y;
         return *this;
     }
+    
     LIMITED_INT< T >& operator /= ( const LIMITED_INT< T > &y )
     {
         *this = *this / y;
         return *this;
     }
+    
     LIMITED_INT< T >& operator /= ( const T y )
     {
         *this = *this / y;

pcbnew/block_module_editor.cpp

@@ -550,9 +550,9 @@ void MirrorMarkedItems( MODULE* module, wxPoint offset )
             continue;
 
         SETMIRROR( pad->GetPosition().x );
-        pad->m_Pos0.x = FROM_LEGACY_LU( pad->GetPosition().x );
-        NEGATE( pad->m_Offset.x );
-        NEGATE( pad->m_DeltaSize.x );
+        pad->m_Pos0.x() = FROM_LEGACY_LU( pad->GetPosition().x );
+        NEGATE( pad->m_Offset.x() );
+        NEGATE( pad->m_DeltaSize.x() );
         pad->m_Orient      = 1800 - pad->m_Orient;
         NORMALIZE_ANGLE_POS( pad->m_Orient );
     }

pcbnew/board_items_to_polygon_shape_transform.cpp

@@ -328,8 +328,8 @@ void D_PAD:: TransformShapeWithClearanceToPolygon( std:: vector < CPolyPt>& aCor
 {
     wxPoint corner_position;
     int     ii, angle;
-    int     dx = TO_LEGACY_LU( m_Size.x / 2 ) + aClearanceValue;
-    int     dy = TO_LEGACY_LU( m_Size.y / 2 ) + aClearanceValue;
+    int     dx = TO_LEGACY_LU( m_Size.x() / 2 ) + aClearanceValue;
+    int     dy = TO_LEGACY_LU( m_Size.y() / 2 ) + aClearanceValue;
 
     int     delta = 3600 / aCircleToSegmentsCount;  // rot angle in 0.1 degree
     wxPoint PadShapePos = ReturnShapePos();         /* Note: for pad having a shape offset,
@@ -437,8 +437,8 @@ void D_PAD:: TransformShapeWithClearanceToPolygon( std:: vector < CPolyPt>& aCor
 
     default:
     case PAD_TRAPEZOID:
-        psize.x += TO_LEGACY_LU( ABS( m_DeltaSize.y ) );
-        psize.y += TO_LEGACY_LU( ABS( m_DeltaSize.x ) );
+        psize.x += TO_LEGACY_LU( abs( m_DeltaSize.y() ) );
+        psize.y += TO_LEGACY_LU( abs( m_DeltaSize.x() ) );
 
     // fall through
     case PAD_RECT:
@@ -572,8 +572,8 @@ void    CreateThermalReliefPadPolygon( std::vector<CPolyPt>& aCornerBuffer,
     wxPoint PadShapePos = aPad.ReturnShapePos();    /* Note: for pad having a shape offset,
                                                      * the pad position is NOT the shape position */
     wxSize  copper_thickness;
-    int     dx = TO_LEGACY_LU( aPad.m_Size.x / 2 );
-    int     dy = TO_LEGACY_LU( aPad.m_Size.y / 2 );
+    int     dx = TO_LEGACY_LU( aPad.m_Size.x() / 2 );
+    int     dy = TO_LEGACY_LU( aPad.m_Size.y() / 2 );
 
     int     delta = 3600 / aCircleToSegmentsCount; // rot angle in 0.1 degree
 
@@ -684,8 +684,8 @@ void    CreateThermalReliefPadPolygon( std::vector<CPolyPt>& aCornerBuffer,
         // Oval pad support along the lines of round and rectangular pads
         std::vector <wxPoint> corners_buffer;               // Polygon buffer as vector
 
-        int     dx = TO_LEGACY_LU( aPad.m_Size.x / 2 ) + aThermalGap;     // Cutout radius x
-        int     dy = TO_LEGACY_LU( aPad.m_Size.y / 2 ) + aThermalGap;     // Cutout radius y
+        int     dx = TO_LEGACY_LU( aPad.m_Size.x() / 2 ) + aThermalGap;     // Cutout radius x
+        int     dy = TO_LEGACY_LU( aPad.m_Size.y() / 2 ) + aThermalGap;     // Cutout radius y
 
         wxPoint shape_offset;
 
@@ -839,8 +839,8 @@ void    CreateThermalReliefPadPolygon( std::vector<CPolyPt>& aCornerBuffer,
 
         std::vector <wxPoint> corners_buffer;               // Polygon buffer as vector
 
-        int dx = TO_LEGACY_LU( aPad.m_Size.x / 2 ) + aThermalGap;         // Cutout radius x
-        int dy = TO_LEGACY_LU( aPad.m_Size.y / 2 ) + aThermalGap;         // Cutout radius y
+        int dx = TO_LEGACY_LU( aPad.m_Size.x() / 2 ) + aThermalGap;         // Cutout radius x
+        int dy = TO_LEGACY_LU( aPad.m_Size.y() / 2 ) + aThermalGap;         // Cutout radius y
 
         // The first point of polygon buffer is left lower corner, second the crosspoint of
         // thermal spoke sides, the third is upper right corner and the rest are rounding

pcbnew/class_module_transform_functions.cpp

@@ -186,9 +186,9 @@ void MODULE::Flip(const wxPoint& aCentre )
         pt_pad->m_Pos.y      -= m_Pos.y;
         pt_pad->m_Pos.y       = -pt_pad->m_Pos.y;
         pt_pad->m_Pos.y      += m_Pos.y;
-        NEGATE( pt_pad->m_Pos0.y );
-        NEGATE( pt_pad->m_Offset.y );
-        NEGATE( pt_pad->m_DeltaSize.y );
+        NEGATE( pt_pad->m_Pos0.y() );
+        NEGATE( pt_pad->m_Offset.y() );
+        NEGATE( pt_pad->m_DeltaSize.y() );
         NEGATE_AND_NORMALIZE_ANGLE_POS( pt_pad->m_Orient );
 
         /* flip pads layers*/
@@ -352,8 +352,8 @@ void MODULE::SetOrientation( int newangle )
 
     for( D_PAD* pad = m_Pads;  pad;  pad = pad->Next() )
     {
-        px = TO_LEGACY_LU( pad->m_Pos0.x );
-        py = TO_LEGACY_LU( pad->m_Pos0.y );
+        px = TO_LEGACY_LU( pad->m_Pos0.x() );
+        py = TO_LEGACY_LU( pad->m_Pos0.y() );
 
         pad->m_Orient += newangle; /* change m_Orientation */
         NORMALIZE_ANGLE_POS( pad->m_Orient );

pcbnew/class_pad.cpp

@@ -27,7 +27,7 @@ D_PAD::D_PAD( MODULE* parent ) : BOARD_CONNECTED_ITEM( parent, PCB_PAD_T )
 {
     m_NumPadName = 0;
 
-    m_Size.x = m_Size.y = FROM_LEGACY_LU( 500 );          // give it a reasonable size
+    m_Size[0] = m_Size[1] = FROM_LEGACY_LU( 500 );          // give it a reasonable size
     /// TODO: remove hardcoded constant
     m_Orient = 0;                       // Pad rotation in 1/10 degrees
     m_LengthDie = ZERO_LENGTH;
@@ -68,23 +68,23 @@ int D_PAD::GetMaxRadius() const
     switch( m_PadShape & 0x7F )
     {
     case PAD_CIRCLE:
-        radius = TO_LEGACY_LU( m_Size.x / 2 );
+        radius = TO_LEGACY_LU( m_Size.x() / 2 );
         break;
 
     case PAD_OVAL:
-        radius = TO_LEGACY_LU( MAX( m_Size.x, m_Size.y ) / 2 );
+        radius = TO_LEGACY_LU( max( m_Size.x(), m_Size.y() ) / 2 );
         break;
 
     case PAD_RECT:
-        x = TO_LEGACY_LU( m_Size.x );
-        y = TO_LEGACY_LU( m_Size.y );
+        x = TO_LEGACY_LU( m_Size.x() );
+        y = TO_LEGACY_LU( m_Size.y() );
         radius = 1 + (int) ( sqrt( (double) y * y
                                    + (double) x * x ) / 2 );
         break;
 
     case PAD_TRAPEZOID:
-        x = TO_LEGACY_LU( m_Size.x + ABS( m_DeltaSize.y ) );   // Remember: m_DeltaSize.y is the m_Size.x change
-        y = TO_LEGACY_LU( m_Size.y + ABS( m_DeltaSize.x ) );   // Remember: m_DeltaSize.x is the m_Size.y change
+        x = TO_LEGACY_LU( m_Size.x() + abs( m_DeltaSize.y() ) );   // Remember: m_DeltaSize.y is the m_Size.x change
+        y = TO_LEGACY_LU( m_Size.y() + abs( m_DeltaSize.x() ) );   // Remember: m_DeltaSize.x is the m_Size.y change
         radius = 1 + (int) ( sqrt( (double) y * y + (double) x * x ) / 2 );
         break;
 
@@ -124,14 +124,14 @@ EDA_RECT D_PAD::GetBoundingBox() const
 // Returns the position of the pad.
 const wxPoint D_PAD::ReturnShapePos()
 {
-    if( m_Offset.x == ZERO_LENGTH && m_Offset.y == ZERO_LENGTH )
+    if( m_Offset[0] == ZERO_LENGTH && m_Offset[0] == ZERO_LENGTH )
         return m_Pos;
 
     wxPoint shape_pos;
     int     dX, dY;
 
-    dX = TO_LEGACY_LU( m_Offset.x );
-    dY = TO_LEGACY_LU( m_Offset.y );
+    dX = TO_LEGACY_LU( m_Offset[0] );
+    dY = TO_LEGACY_LU( m_Offset[1] );
 
     RotatePoint( &dX, &dY, m_Orient );
 
@@ -304,7 +304,7 @@ int D_PAD::GetSolderMaskMargin()
     // ensure mask have a size always >= 0
     if( margin < 0 )
     {
-        int minsize = TO_LEGACY_LU( -MIN( m_Size.x, m_Size.y ) / 2 );
+        int minsize = TO_LEGACY_LU( -min( m_Size.x(), m_Size.y() ) / 2 );
 
         if( margin < minsize )
             minsize = minsize;
@@ -349,15 +349,15 @@ wxSize D_PAD::GetSolderPasteMargin()
     }
 
     wxSize pad_margin;
-    pad_margin.x = margin + wxRound( TO_LEGACY_LU_DBL( m_Size.x ) * mratio );
-    pad_margin.y = margin + wxRound( TO_LEGACY_LU_DBL( m_Size.y ) * mratio );
+    pad_margin.x = margin + wxRound( TO_LEGACY_LU_DBL( m_Size.x() ) * mratio );
+    pad_margin.y = margin + wxRound( TO_LEGACY_LU_DBL( m_Size.y() ) * mratio );
 
     // ensure mask have a size always >= 0
-    if( pad_margin.x < TO_LEGACY_LU( -m_Size.x / 2 ) )
-        pad_margin.x = TO_LEGACY_LU( -m_Size.x / 2 );
+    if( pad_margin.x < TO_LEGACY_LU( -m_Size.x() / 2 ) )
+        pad_margin.x = TO_LEGACY_LU( -m_Size.x() / 2 );
 
-    if( pad_margin.y < TO_LEGACY_LU( -m_Size.y / 2 ) )
-        pad_margin.y = TO_LEGACY_LU( -m_Size.y / 2 );
+    if( pad_margin.y < TO_LEGACY_LU( -m_Size.y() / 2 ) )
+        pad_margin.y = TO_LEGACY_LU( -m_Size.y() / 2 );
 
     return pad_margin;
 }
@@ -426,10 +426,10 @@ int D_PAD::ReadDescr( LINE_READER* aReader )
                          BufCar, &sx, &sy,
                          &dx, &dy,
                          &m_Orient );
-            m_Size.x = LENGTH_LOAD_TMP( sx );
-            m_Size.y = LENGTH_LOAD_TMP( sy );
-            m_DeltaSize.x = LENGTH_LOAD_TMP( dx );
-            m_DeltaSize.y = LENGTH_LOAD_TMP( dy );
+            m_Size.x() = LENGTH_LOAD_TMP( sx );
+            m_Size.y() = LENGTH_LOAD_TMP( sy );
+            m_DeltaSize.x() = LENGTH_LOAD_TMP( dx );
+            m_DeltaSize.y() = LENGTH_LOAD_TMP( dy );
             ll = 0xFF & BufCar[0];
 
             /* Read pad shape */
@@ -457,17 +457,17 @@ int D_PAD::ReadDescr( LINE_READER* aReader )
             BufCar[0] = 0;
             nn = sscanf( PtLine, FM_LENLD" "FM_LENLD" "FM_LENLD" %s "FM_LENLD" "FM_LENLD, &dr,
                          &ox, &oy, BufCar, &dx, &dy );
-            m_Offset.x    = LENGTH_LOAD_TMP( ox );
-            m_Offset.y    = LENGTH_LOAD_TMP( oy );
-            m_Drill.y    = m_Drill.x = LENGTH_LOAD_TMP( dr );
+            m_Offset.x()              = LENGTH_LOAD_TMP( ox );
+            m_Offset.y()              = LENGTH_LOAD_TMP( oy );
+            m_Drill.y() = m_Drill.x() = LENGTH_LOAD_TMP( dr );
             m_DrillShape = PAD_CIRCLE;
 
             if( nn >= 6 )       // Drill shape = OVAL ?
             {
                 if( BufCar[0] == 'O' )
                 {
-                    m_Drill.x    = FROM_LEGACY_LU( dx );
-                    m_Drill.y    = FROM_LEGACY_LU( dy );
+                    m_Drill.x()  = FROM_LEGACY_LU( dx );
+                    m_Drill.y()  = FROM_LEGACY_LU( dy );
                     m_DrillShape = PAD_OVAL;
                 }
             }
@@ -503,7 +503,7 @@ int D_PAD::ReadDescr( LINE_READER* aReader )
 
         case 'P':
             nn    = sscanf( PtLine, FM_LENLD" "FM_LENLD, &ox, &oy );
-            m_Pos0 = VECTOR_PCB( LENGTH_LOAD_TMP( ox ), LENGTH_LOAD_TMP( oy ) );
+            m_Pos0 = VECTOR_PCB::fromXY( LENGTH_LOAD_TMP( ox ), LENGTH_LOAD_TMP( oy ) );
             m_Pos = TO_LEGACY_LU_WXP( m_Pos0 );
             break;
 
@@ -563,14 +563,14 @@ bool D_PAD::Save( FILE* aFile ) const
     }
 
     fprintf( aFile, "Sh \"%.4s\" %c "FM_LENSV" "FM_LENSV" "FM_LENSV" "FM_LENSV" %d\n", // TODO: pad name length limit!
-             m_Padname, cshape, ARG_LENSV( m_Size.x ), ARG_LENSV( m_Size.y ),
-             ARG_LENSV( m_DeltaSize.x ), ARG_LENSV( m_DeltaSize.y ), m_Orient );
+             m_Padname, cshape, ARG_LENSV( m_Size.x() ), ARG_LENSV( m_Size.y() ),
+             ARG_LENSV( m_DeltaSize.x() ), ARG_LENSV( m_DeltaSize.y() ), m_Orient );
 
-    fprintf( aFile, "Dr "FM_LENSV" "FM_LENSV" "FM_LENSV, ARG_LENSV( m_Drill.x ), ARG_LENSV( m_Offset.x ), ARG_LENSV( m_Offset.y ) );
+    fprintf( aFile, "Dr "FM_LENSV" "FM_LENSV" "FM_LENSV, ARG_LENSV( m_Drill.x() ), ARG_LENSV( m_Offset.x() ), ARG_LENSV( m_Offset.y() ) );
 
     if( m_DrillShape == PAD_OVAL )
     {
-        fprintf( aFile, " %c "FM_LENSV" "FM_LENSV, 'O', ARG_LENSV( m_Drill.x ), ARG_LENSV( m_Drill.y ) );
+        fprintf( aFile, " %c "FM_LENSV" "FM_LENSV, 'O', ARG_LENSV( m_Drill.x() ), ARG_LENSV( m_Drill.y() ) );
     }
 
     fprintf( aFile, "\n" );
@@ -599,7 +599,7 @@ bool D_PAD::Save( FILE* aFile ) const
 
     fprintf( aFile, "Ne %d %s\n", GetNet(), EscapedUTF8( m_Netname ).c_str() );
 
-    fprintf( aFile, "Po "FM_LENSV" "FM_LENSV"\n", ARG_LENSV( m_Pos0.x ), ARG_LENSV( m_Pos0.y ) );
+    fprintf( aFile, "Po "FM_LENSV" "FM_LENSV"\n", ARG_LENSV( m_Pos0.x() ), ARG_LENSV( m_Pos0.y() ) );
 
     if( m_LengthDie != ZERO_LENGTH )
         fprintf( aFile, "Le "FM_LENSV"\n", ARG_LENSV( m_LengthDie ) );
@@ -755,13 +755,13 @@ void D_PAD::DisplayInfo( EDA_DRAW_FRAME* frame )
 
     frame->AppendMsgPanel( ShowPadShape(), ShowPadAttr(), DARKGREEN );
 
-    valeur_param( TO_LEGACY_LU( m_Size.x ), Line );
+    valeur_param( TO_LEGACY_LU( m_Size.x() ), Line );
     frame->AppendMsgPanel( _( "H Size" ), Line, RED );
 
-    valeur_param( TO_LEGACY_LU( m_Size.y ), Line );
+    valeur_param( TO_LEGACY_LU( m_Size.y() ), Line );
     frame->AppendMsgPanel( _( "V Size" ), Line, RED );
 
-    valeur_param( (unsigned)(int) TO_LEGACY_LU( m_Drill.x ), Line );
+    valeur_param( (unsigned)(int) TO_LEGACY_LU( m_Drill.x() ), Line );
 
     if( m_DrillShape == PAD_CIRCLE )
     {
@@ -769,9 +769,9 @@ void D_PAD::DisplayInfo( EDA_DRAW_FRAME* frame )
     }
     else
     {
-        valeur_param( (unsigned) TO_LEGACY_LU( m_Drill.x ), Line );
+        valeur_param( (unsigned) TO_LEGACY_LU( m_Drill.x() ), Line );
         wxString msg;
-        valeur_param( (unsigned) TO_LEGACY_LU( m_Drill.y ), msg );
+        valeur_param( (unsigned) TO_LEGACY_LU( m_Drill.y() ), msg );
         Line += wxT( " / " ) + msg;
         frame->AppendMsgPanel( _( "Drill X / Y" ), Line, RED );
     }
@@ -827,8 +827,8 @@ bool D_PAD::HitTest( const wxPoint& refPos )
     if( ( abs( delta.x ) > m_ShapeMaxRadius ) || ( abs( delta.y ) > m_ShapeMaxRadius ) )
         return false;
 
-    dx = TO_LEGACY_LU( m_Size.x / 2 ); // dx also is the radius for rounded pads
-    dy = TO_LEGACY_LU( m_Size.y / 2 );
+    dx = TO_LEGACY_LU( m_Size.x() / 2 ); // dx also is the radius for rounded pads
+    dy = TO_LEGACY_LU( m_Size.y() / 2 );
 
     switch( m_PadShape & 0x7F )
     {
@@ -868,22 +868,22 @@ int D_PAD::Compare( const D_PAD* padref, const D_PAD* padcmp )
     if( ( diff = padref->m_PadShape - padcmp->m_PadShape) )
         return diff;
 
-    if( ( diff = TO_LEGACY_LU( padref->m_Size.x - padcmp->m_Size.x ) ) )
+    if( ( diff = TO_LEGACY_LU( padref->m_Size.x() - padcmp->m_Size.x() ) ) )
         return diff;
 
-    if( ( diff = TO_LEGACY_LU( padref->m_Size.y - padcmp->m_Size.y ) ) )
+    if( ( diff = TO_LEGACY_LU( padref->m_Size.y() - padcmp->m_Size.y() ) ) )
         return diff;
 
-    if( ( diff = TO_LEGACY_LU( padref->m_Offset.x - padcmp->m_Offset.x ) ) )
+    if( ( diff = TO_LEGACY_LU( padref->m_Offset.x() - padcmp->m_Offset.x() ) ) )
         return diff;
 
-    if( ( diff = TO_LEGACY_LU( padref->m_Offset.y - padcmp->m_Offset.y ) ) )
+    if( ( diff = TO_LEGACY_LU( padref->m_Offset.y() - padcmp->m_Offset.y() ) ) )
         return diff;
 
-    if( ( diff = TO_LEGACY_LU( padref->m_DeltaSize.x - padcmp->m_DeltaSize.x ) ) )
+    if( ( diff = TO_LEGACY_LU( padref->m_DeltaSize.x() - padcmp->m_DeltaSize.x() ) ) )
         return diff;
 
-    if( ( diff = TO_LEGACY_LU( padref->m_DeltaSize.y - padcmp->m_DeltaSize.y ) ) )
+    if( ( diff = TO_LEGACY_LU( padref->m_DeltaSize.y() - padcmp->m_DeltaSize.y() ) ) )
         return diff;
 
     // @todo check if export_gencad still works:

pcbnew/class_pad_draw_functions.cpp

@@ -476,7 +476,7 @@ void D_PAD::DrawShape( EDA_RECT* aClipBox, wxDC* aDC, PAD_DRAWINFO& aDrawInfo )
 
     /* Draw the pad hole */
     wxPoint holepos = m_Pos - aDrawInfo.m_Offset;
-    int     hole    = TO_LEGACY_LU( m_Drill.x ) / 2;
+    int     hole    = TO_LEGACY_LU( m_Drill.x() ) / 2;
 
     bool drawhole = hole > 0;
 
@@ -513,20 +513,20 @@ void D_PAD::DrawShape( EDA_RECT* aClipBox, wxDC* aDC, PAD_DRAWINFO& aDrawInfo )
             break;
 
         case PAD_OVAL:
-            halfsize.x = TO_LEGACY_LU( m_Drill.x ) / 2;
-            halfsize.y = TO_LEGACY_LU( m_Drill.y ) / 2;
+            halfsize.x = TO_LEGACY_LU( m_Drill.x() ) / 2;
+            halfsize.y = TO_LEGACY_LU( m_Drill.y() ) / 2;
 
-            if( m_Drill.x > m_Drill.y )  /* horizontal */
+            if( m_Drill.x() > m_Drill.y() )  /* horizontal */
             {
                 delta_cx = halfsize.x - halfsize.y;
                 delta_cy = 0;
-                seg_width    = TO_LEGACY_LU( m_Drill.y );
+                seg_width    = TO_LEGACY_LU( m_Drill.y() );
             }
             else                         /* vertical */
             {
                 delta_cx = 0;
                 delta_cy = halfsize.y - halfsize.x;
-                seg_width    = TO_LEGACY_LU( m_Drill.x );
+                seg_width    = TO_LEGACY_LU( m_Drill.x() );
             }
 
             RotatePoint( &delta_cx, &delta_cy, angle );
@@ -578,11 +578,11 @@ void D_PAD::DrawShape( EDA_RECT* aClipBox, wxDC* aDC, PAD_DRAWINFO& aDrawInfo )
 
     AreaSize = TO_LEGACY_LU_WXS( m_Size );
 
-    if( m_Size.y > m_Size.x )
+    if( m_Size.y() > m_Size.x() )
     {
         angle += 900;
-        AreaSize.x = TO_LEGACY_LU( m_Size.y );
-        AreaSize.y = TO_LEGACY_LU( m_Size.x );
+        AreaSize.x = TO_LEGACY_LU( m_Size.y() );
+        AreaSize.y = TO_LEGACY_LU( m_Size.x() );
     }
 
     if( shortname_len > 0 )       // if there is a netname, provides room to display this netname
@@ -664,23 +664,23 @@ int D_PAD::BuildSegmentFromOvalShape(wxPoint& aSegStart, wxPoint& aSegEnd, int a
 {
     int width;
 
-    if( m_Size.y < m_Size.x )     // Build an horizontal equiv segment
+    if( m_Size.y() < m_Size.x() )     // Build an horizontal equiv segment
     {
-        int delta   = TO_LEGACY_LU( ( m_Size.x - m_Size.y ) / 2 );
+        int delta   = TO_LEGACY_LU( ( m_Size.x() - m_Size.y() ) / 2 );
         aSegStart.x = -delta;
         aSegStart.y = 0;
         aSegEnd.x = delta;
         aSegEnd.y = 0;
-        width = TO_LEGACY_LU( m_Size.y );
+        width = TO_LEGACY_LU( m_Size.y() );
     }
     else        // Vertical oval: build a vertical equiv segment
     {
-        int delta   = TO_LEGACY_LU( ( m_Size.y -m_Size.x ) / 2 );
+        int delta   = TO_LEGACY_LU( ( m_Size.y() -m_Size.x() ) / 2 );
         aSegStart.x = 0;
         aSegStart.y = -delta;
         aSegEnd.x = 0;
         aSegEnd.y = delta;
-        width = TO_LEGACY_LU( m_Size.x );
+        width = TO_LEGACY_LU( m_Size.x() );
     }
 
     if( aRotation )
@@ -701,8 +701,8 @@ void D_PAD::BuildPadPolygon( wxPoint aCoord[4], wxSize aInflateValue, int aRotat
     wxSize delta;
     wxSize halfsize;
 
-    halfsize.x = TO_LEGACY_LU( m_Size.x / 2 );
-    halfsize.y = TO_LEGACY_LU( m_Size.y / 2 );
+    halfsize.x = TO_LEGACY_LU( m_Size.x() / 2 );
+    halfsize.y = TO_LEGACY_LU( m_Size.y() / 2 );
 
     /* For rectangular shapes, inflate is easy
      */
@@ -721,8 +721,8 @@ void D_PAD::BuildPadPolygon( wxPoint aCoord[4], wxSize aInflateValue, int aRotat
     else
     {
         // Trapezoidal pad: verify delta values
-        delta.x = TO_LEGACY_LU( m_DeltaSize.x / 2 );
-        delta.y = TO_LEGACY_LU( m_DeltaSize.y / 2 );
+        delta.x = TO_LEGACY_LU( m_DeltaSize.x() / 2 );
+        delta.y = TO_LEGACY_LU( m_DeltaSize.y() / 2 );
 
         // be sure delta values are not to large
         if( (delta.x < 0) && (delta.x <= -halfsize.y) )
@@ -762,7 +762,7 @@ void D_PAD::BuildPadPolygon( wxPoint aCoord[4], wxSize aInflateValue, int aRotat
         if( delta.y )    // lower and upper segment is horizontal
         {
             // Calculate angle of left (or right) segment with vertical axis
-            angle = atan2( m_DeltaSize.y, m_Size.y ); /// TODO: make atan2 available to LENGTH
+            angle = atan2( m_DeltaSize.y(), m_Size.y() );
 
             // left and right sides are moved by aInflateValue.x in their perpendicular direction
             // We must calculate the corresponding displacement on the horizontal axis
@@ -778,7 +778,7 @@ void D_PAD::BuildPadPolygon( wxPoint aCoord[4], wxSize aInflateValue, int aRotat
         else if( delta.x )          // left and right segment is vertical
         {
             // Calculate angle of lower (or upper) segment with horizontal axis
-            angle = atan2( m_DeltaSize.x, m_Size.x );
+            angle = atan2( m_DeltaSize.x(), m_Size.x() );
 
             // lower and upper sides are moved by aInflateValue.x in their perpendicular direction
             // We must calculate the corresponding displacement on the vertical axis

pcbnew/dialogs/dialog_gendrill.cpp

@@ -185,7 +185,7 @@ void DIALOG_GENDRILL::InitDisplayParams( void )
         {
             if( pad->m_DrillShape == PAD_CIRCLE )
             {
-                if( pad->m_Drill.x != ZERO_LENGTH )
+                if( pad->m_Drill.x() != ZERO_LENGTH )
                 {
                     if( pad->m_Attribut == PAD_HOLE_NOT_PLATED )
                         m_notplatedPadsHoleCount++;
@@ -195,7 +195,7 @@ void DIALOG_GENDRILL::InitDisplayParams( void )
             }
             else
             {
-                if( MIN( TO_LEGACY_LU( pad->m_Drill.x ), TO_LEGACY_LU( pad->m_Drill.y ) ) != 0 )
+                if( min( TO_LEGACY_LU( pad->m_Drill.x() ), TO_LEGACY_LU( pad->m_Drill.y() ) ) != 0 )
                 {
                     if( pad->m_Attribut == PAD_HOLE_NOT_PLATED )
                         m_notplatedPadsHoleCount++;

pcbnew/dialogs/dialog_pad_properties.cpp

@@ -130,11 +130,11 @@ void DIALOG_PAD_PROPERTIES::OnPaintShowPanel( wxPaintEvent& event )
     dc.SetDeviceOrigin( dc_size.x / 2, dc_size.y / 2 );
 
     // Calculate a suitable scale to fit the available draw area
-    int dim = TO_LEGACY_LU( m_dummyPad->m_Size.x + ABS( m_dummyPad->m_DeltaSize.y ) );
+    int dim = TO_LEGACY_LU( m_dummyPad->m_Size.x() + abs( m_dummyPad->m_DeltaSize.y() ) );
     if( m_dummyPad->m_LocalClearance > ZERO_LENGTH )
         dim += TO_LEGACY_LU( m_dummyPad->m_LocalClearance * 2 );
     double scale    = (double) dc_size.x / dim;
-    dim = TO_LEGACY_LU( m_dummyPad->m_Size.y + ABS( m_dummyPad->m_DeltaSize.x ) );
+    dim = TO_LEGACY_LU( m_dummyPad->m_Size.y() + abs( m_dummyPad->m_DeltaSize.x() ) );
     if( m_dummyPad->m_LocalClearance > ZERO_LENGTH )
         dim += TO_LEGACY_LU( m_dummyPad->m_LocalClearance * 2 );
     double altscale = (double) dc_size.y / dim;
@@ -207,8 +207,8 @@ void DIALOG_PAD_PROPERTIES::initValues()
 
     if( m_isFlipped )
     {
-        NEGATE( m_dummyPad->m_Offset.y );
-        NEGATE( m_dummyPad->m_DeltaSize.y );
+        NEGATE( m_dummyPad->m_Offset.y() );
+        NEGATE( m_dummyPad->m_DeltaSize.y() );
         /* flip pads layers*/
         m_dummyPad->m_layerMask = ChangeSideMaskLayer( m_dummyPad->m_layerMask );
     }
@@ -239,23 +239,23 @@ void DIALOG_PAD_PROPERTIES::initValues()
     PutValueInLocalUnits( *m_PadPosition_X_Ctrl, m_dummyPad->m_Pos.x, internalUnits );
     PutValueInLocalUnits( *m_PadPosition_Y_Ctrl, m_dummyPad->m_Pos.y, internalUnits );
 
-    CTR_PUT_LENGTH( *m_PadDrill_X_Ctrl, m_dummyPad->m_Drill.x, internalUnits );
-    CTR_PUT_LENGTH( *m_PadDrill_Y_Ctrl, m_dummyPad->m_Drill.y, internalUnits );
+    CTR_PUT_LENGTH( *m_PadDrill_X_Ctrl, m_dummyPad->m_Drill.x(), internalUnits );
+    CTR_PUT_LENGTH( *m_PadDrill_Y_Ctrl, m_dummyPad->m_Drill.y(), internalUnits );
 
-    CTR_PUT_LENGTH( *m_ShapeSize_X_Ctrl, m_dummyPad->m_Size.x, internalUnits );
-    CTR_PUT_LENGTH( *m_ShapeSize_Y_Ctrl, m_dummyPad->m_Size.y, internalUnits );
+    CTR_PUT_LENGTH( *m_ShapeSize_X_Ctrl, m_dummyPad->m_Size.x(), internalUnits );
+    CTR_PUT_LENGTH( *m_ShapeSize_Y_Ctrl, m_dummyPad->m_Size.y(), internalUnits );
 
-    CTR_PUT_LENGTH( *m_ShapeOffset_X_Ctrl, m_dummyPad->m_Offset.x, internalUnits );
-    CTR_PUT_LENGTH( *m_ShapeOffset_Y_Ctrl, m_dummyPad->m_Offset.y, internalUnits );
+    CTR_PUT_LENGTH( *m_ShapeOffset_X_Ctrl, m_dummyPad->m_Offset.x(), internalUnits );
+    CTR_PUT_LENGTH( *m_ShapeOffset_Y_Ctrl, m_dummyPad->m_Offset.y(), internalUnits );
 
-    if( m_dummyPad->m_DeltaSize.x != ZERO_LENGTH )
+    if( m_dummyPad->m_DeltaSize.x() != ZERO_LENGTH )
     {
-        CTR_PUT_LENGTH( *m_ShapeDelta_Ctrl, m_dummyPad->m_DeltaSize.x, internalUnits );
+        CTR_PUT_LENGTH( *m_ShapeDelta_Ctrl, m_dummyPad->m_DeltaSize.x(), internalUnits );
         m_radioBtnDeltaXdir->SetValue(true);
     }
     else
     {
-        CTR_PUT_LENGTH( *m_ShapeDelta_Ctrl, m_dummyPad->m_DeltaSize.y, internalUnits );
+        CTR_PUT_LENGTH( *m_ShapeDelta_Ctrl, m_dummyPad->m_DeltaSize.y(), internalUnits );
         m_radioBtnDeltaYdir->SetValue(true);
     }
 
@@ -621,12 +621,12 @@ void DIALOG_PAD_PROPERTIES::PadPropertiesAccept( wxCommandEvent& event )
 	m_CurrentPad->m_Pos0 = FROM_LEGACY_LU_VEC( p );
 
         m_CurrentPad->m_Size = g_Pad_Master.m_Size;
-        m_CurrentPad->m_DeltaSize    = g_Pad_Master.m_DeltaSize;
-        m_CurrentPad->m_DeltaSize.y *= isign;
-        m_CurrentPad->m_Drill = g_Pad_Master.m_Drill;
-        m_CurrentPad->m_DrillShape = g_Pad_Master.m_DrillShape;
-        m_CurrentPad->m_Offset     = g_Pad_Master.m_Offset;
-        m_CurrentPad->m_Offset.y  *= isign;
+        m_CurrentPad->m_DeltaSize      = g_Pad_Master.m_DeltaSize;
+        m_CurrentPad->m_DeltaSize.y() *= isign;
+        m_CurrentPad->m_Drill          = g_Pad_Master.m_Drill;
+        m_CurrentPad->m_DrillShape     = g_Pad_Master.m_DrillShape;
+        m_CurrentPad->m_Offset         = g_Pad_Master.m_Offset;
+        m_CurrentPad->m_Offset.y()    *= isign;
 
         m_CurrentPad->m_LengthDie = g_Pad_Master.m_LengthDie;
 
@@ -716,21 +716,21 @@ bool DIALOG_PAD_PROPERTIES::TransfertDataToPad( D_PAD* aPad, bool aPromptOnError
     aPad->m_Pos0  = FROM_LEGACY_LU_VEC( aPad->m_Pos );
 
     // Read pad drill:
-    aPad->m_Drill.x = CTR_GET_LENGTH( *m_PadDrill_X_Ctrl, internalUnits );
-    aPad->m_Drill.y = CTR_GET_LENGTH( *m_PadDrill_Y_Ctrl, internalUnits );
+    aPad->m_Drill.x() = CTR_GET_LENGTH( *m_PadDrill_X_Ctrl, internalUnits );
+    aPad->m_Drill.y() = CTR_GET_LENGTH( *m_PadDrill_Y_Ctrl, internalUnits );
     if( m_DrillShapeCtrl->GetSelection() == 0 )
     {
         aPad->m_DrillShape = PAD_CIRCLE;
-        aPad->m_Drill.y    = aPad->m_Drill.x;
+        aPad->m_Drill.y()  = aPad->m_Drill.x();
     }
     else
         aPad->m_DrillShape = PAD_OVAL;
 
     // Read pad shape size:
-    aPad->m_Size.x = CTR_GET_LENGTH( *m_ShapeSize_X_Ctrl, internalUnits );
-    aPad->m_Size.y = CTR_GET_LENGTH( *m_ShapeSize_Y_Ctrl, internalUnits );
+    aPad->m_Size.x() = CTR_GET_LENGTH( *m_ShapeSize_X_Ctrl, internalUnits );
+    aPad->m_Size.y() = CTR_GET_LENGTH( *m_ShapeSize_Y_Ctrl, internalUnits );
     if( aPad->m_PadShape == PAD_CIRCLE )
-        aPad->m_Size.y = aPad->m_Size.x;
+        aPad->m_Size.y() = aPad->m_Size.x();
 
     // Read pad shape delta size:
     // m_DeltaSize.x or m_DeltaSize.y must be NULL. for a trapezoid.
@@ -738,8 +738,8 @@ bool DIALOG_PAD_PROPERTIES::TransfertDataToPad( D_PAD* aPad, bool aPromptOnError
     LENGTH_PCB delta;
     delta = CTR_GET_LENGTH( *m_ShapeDelta_Ctrl, internalUnits );
     aPad->m_DeltaSize = m_radioBtnDeltaXdir->GetValue()?
-        VECTOR_PCB( delta, ZERO_LENGTH ):
-        VECTOR_PCB( ZERO_LENGTH, delta );
+        VECTOR_PCB::fromXY( delta, ZERO_LENGTH ):
+        VECTOR_PCB::fromXY( ZERO_LENGTH, delta );
 
     // Read pad lenght die
     aPad->m_LengthDie = CTR_GET_LENGTH( *m_LengthDieCtrl, internalUnits );
@@ -747,30 +747,30 @@ bool DIALOG_PAD_PROPERTIES::TransfertDataToPad( D_PAD* aPad, bool aPromptOnError
     // Test bad values (be sure delta values are not to large)
     // remember DeltaSize.x is the Y size variation TODO: this can be optimized
     bool   error    = false;
-    if( (aPad->m_DeltaSize.x < ZERO_LENGTH) && (aPad->m_DeltaSize.x <= -aPad->m_Size.y ) )
+    if( (aPad->m_DeltaSize.x() < ZERO_LENGTH) && (aPad->m_DeltaSize.x() <= -aPad->m_Size.y() ) )
     {
-        aPad->m_DeltaSize.x = -aPad->m_Size.y + FROM_LEGACY_LU( 2 );
+        aPad->m_DeltaSize.x() = -aPad->m_Size.y() + FROM_LEGACY_LU( 2 );
         error = true;
     }
-    if( (aPad->m_DeltaSize.x > ZERO_LENGTH) && (aPad->m_DeltaSize.x >= aPad->m_Size.y ) )
+    if( (aPad->m_DeltaSize.x() > ZERO_LENGTH) && (aPad->m_DeltaSize.x() >= aPad->m_Size.y() ) )
     {
-        aPad->m_DeltaSize.x = aPad->m_Size.y - FROM_LEGACY_LU( 2 );
+        aPad->m_DeltaSize.x() = aPad->m_Size.y() - FROM_LEGACY_LU( 2 );
         error = true;
     }
-    if( (aPad->m_DeltaSize.y < ZERO_LENGTH) && (aPad->m_DeltaSize.y <= -aPad->m_Size.x ) )
+    if( (aPad->m_DeltaSize.y() < ZERO_LENGTH) && (aPad->m_DeltaSize.y() <= -aPad->m_Size.x() ) )
     {
-        aPad->m_DeltaSize.y = -aPad->m_Size.x + FROM_LEGACY_LU( 2 );
+        aPad->m_DeltaSize.y() = -aPad->m_Size.x() + FROM_LEGACY_LU( 2 );
         error = true;
     }
-    if( (aPad->m_DeltaSize.y > ZERO_LENGTH) && (aPad->m_DeltaSize.y >= aPad->m_Size.x ) )
+    if( (aPad->m_DeltaSize.y() > ZERO_LENGTH) && (aPad->m_DeltaSize.y() >= aPad->m_Size.x() ) )
     {
-        aPad->m_DeltaSize.y = aPad->m_Size.x - FROM_LEGACY_LU( 2 );
+        aPad->m_DeltaSize.y() = aPad->m_Size.x() - FROM_LEGACY_LU( 2 );
         error = true;
     }
 
     // Read pad shape offset:
-    aPad->m_Offset.x = CTR_GET_LENGTH( *m_ShapeOffset_X_Ctrl, internalUnits );
-    aPad->m_Offset.y = CTR_GET_LENGTH( *m_ShapeOffset_Y_Ctrl, internalUnits );
+    aPad->m_Offset.x() = CTR_GET_LENGTH( *m_ShapeOffset_X_Ctrl, internalUnits );
+    aPad->m_Offset.y() = CTR_GET_LENGTH( *m_ShapeOffset_Y_Ctrl, internalUnits );
 
     long orient_value = 0;
     msg = m_PadOrientCtrl->GetValue();
@@ -785,17 +785,17 @@ bool DIALOG_PAD_PROPERTIES::TransfertDataToPad( D_PAD* aPad, bool aPromptOnError
     switch( aPad->m_PadShape )
     {
     case PAD_CIRCLE:
-        aPad->m_Offset    = VECTOR_PCB( ZERO_LENGTH, ZERO_LENGTH ); // wxSize( 0, 0 );
-        aPad->m_DeltaSize = VECTOR_PCB( ZERO_LENGTH, ZERO_LENGTH );
-        aPad->m_Size.y    = aPad->m_Size.x;
+        aPad->m_Offset    = VECTOR_PCB::fromXY( ZERO_LENGTH, ZERO_LENGTH ); // wxSize( 0, 0 );
+        aPad->m_DeltaSize = VECTOR_PCB::fromXY( ZERO_LENGTH, ZERO_LENGTH );
+        aPad->m_Size.y()    = aPad->m_Size.x();
         break;
 
     case PAD_RECT:
-        aPad->m_DeltaSize = VECTOR_PCB( ZERO_LENGTH, ZERO_LENGTH );
+        aPad->m_DeltaSize = VECTOR_PCB::fromXY( ZERO_LENGTH, ZERO_LENGTH );
         break;
 
     case PAD_OVAL:
-        aPad->m_DeltaSize = VECTOR_PCB( ZERO_LENGTH, ZERO_LENGTH );
+        aPad->m_DeltaSize = VECTOR_PCB::fromXY( ZERO_LENGTH, ZERO_LENGTH );
         break;
 
     case PAD_TRAPEZOID:
@@ -809,14 +809,14 @@ bool DIALOG_PAD_PROPERTIES::TransfertDataToPad( D_PAD* aPad, bool aPromptOnError
 
     case PAD_CONN:
     case PAD_SMD:
-        aPad->m_Offset = VECTOR_PCB( ZERO_LENGTH, ZERO_LENGTH );
-        aPad->m_Drill  = VECTOR_PCB( ZERO_LENGTH, ZERO_LENGTH );
+        aPad->m_Offset = VECTOR_PCB::fromXY( ZERO_LENGTH, ZERO_LENGTH );
+        aPad->m_Drill  = VECTOR_PCB::fromXY( ZERO_LENGTH, ZERO_LENGTH );
         break;
 
     case PAD_HOLE_NOT_PLATED:
         // Mechanical purpose only:
         // no offset, no net name, no pad name allowed
-        aPad->m_Offset = VECTOR_PCB( ZERO_LENGTH, ZERO_LENGTH ); //wxSize( 0, 0 );
+        aPad->m_Offset = VECTOR_PCB::fromXY( ZERO_LENGTH, ZERO_LENGTH ); //wxSize( 0, 0 );
         aPad->SetPadName( wxEmptyString );
         aPad->SetNetname( wxEmptyString );
         break;
@@ -873,8 +873,8 @@ bool DIALOG_PAD_PROPERTIES::TransfertDataToPad( D_PAD* aPad, bool aPromptOnError
     /* Test for incorrect values */
     if( aPromptOnError )
     {
-        if( (aPad->m_Size.x < aPad->m_Drill.x )
-           || (aPad->m_Size.y < aPad->m_Drill.y ) )
+        if( (aPad->m_Size.x() < aPad->m_Drill.x() )
+           || (aPad->m_Size.y() < aPad->m_Drill.y() ) )
         {
             DisplayError( NULL, _( "Incorrect value for pad drill: pad drill bigger than pad size" ) );
             return false;
@@ -883,7 +883,7 @@ bool DIALOG_PAD_PROPERTIES::TransfertDataToPad( D_PAD* aPad, bool aPromptOnError
         int padlayers_mask = PadLayerMask & (LAYER_BACK | LAYER_FRONT);
         if( padlayers_mask == 0 )
         {
-            if( aPad->m_Drill.x != ZERO_LENGTH || aPad->m_Drill.y != ZERO_LENGTH )
+            if( aPad->m_Drill.x() != ZERO_LENGTH || aPad->m_Drill.y() != ZERO_LENGTH )
             {
                 msg = _( "Error: pad is not on a copper layer and has a hole" );
                 if( aPad->m_Attribut == PAD_HOLE_NOT_PLATED )
@@ -897,8 +897,8 @@ if you do not want this pad plotted in gerber files");
             }
         }
 
-        if( ( aPad->m_Size.x / 2 <= ABS( aPad->m_Offset.x ) )
-           || ( aPad->m_Size.y / 2 <= ABS( aPad->m_Offset.y ) ) )
+        if( ( aPad->m_Size.x() / 2 <= abs( aPad->m_Offset.x() ) )
+           || ( aPad->m_Size.y() / 2 <= abs( aPad->m_Offset.y() ) ) )
         {
             DisplayError( NULL, _( "Incorrect value for pad offset" ) );
             return false;

pcbnew/drc.cpp

@@ -617,7 +617,7 @@ bool DRC::doPadToPadsDrc( D_PAD* aRefPad, D_PAD** aStart, D_PAD** aEnd, int x_li
             /* Here, we must test clearance between holes and pads
              * dummy pad size and shape is adjusted to pad drill size and shape
              */
-            if( pad->m_Drill.x != ZERO_LENGTH )
+            if( pad->m_Drill.x() != ZERO_LENGTH )
             {
                 // pad under testing has a hole, test this hole against pad reference
                 dummypad.SetPosition( pad->GetPosition() );
@@ -637,7 +637,7 @@ bool DRC::doPadToPadsDrc( D_PAD* aRefPad, D_PAD** aStart, D_PAD** aEnd, int x_li
                 }
             }
 
-            if( aRefPad->m_Drill.x != ZERO_LENGTH ) // pad reference has a hole
+            if( aRefPad->m_Drill.x() != ZERO_LENGTH ) // pad reference has a hole
             {
                 dummypad.SetPosition( aRefPad->GetPosition() );
                 dummypad.m_Size     = aRefPad->m_Drill;

pcbnew/drc_clearance_test_functions.cpp

@@ -290,7 +290,7 @@ bool DRC::doTrackDrc( TRACK* aRefSeg, TRACK* aStart, bool testPads )
                  * checkClearanceSegmToPad(),a pseudo pad is used, with a shape and a
                  * size like the hole
                  */
-                if( pad->m_Drill.x == ZERO_LENGTH )
+                if( pad->m_Drill.x() == ZERO_LENGTH )
                     continue;
 
                 dummypad.m_Size     = pad->m_Drill;
@@ -633,7 +633,7 @@ bool DRC::checkClearancePadToPad( D_PAD* aRefPad, D_PAD* aPad )
         m_segmEnd.x = m_segmEnd.y = 0;
 
         m_padToTestPos = relativePadPos;
-        diag = checkClearanceSegmToPad( aPad, TO_LEGACY_LU( aRefPad->m_Size.x ), dist_min );
+        diag = checkClearanceSegmToPad( aPad, TO_LEGACY_LU( aRefPad->m_Size.x() ), dist_min );
         break;
 
     case PAD_RECT:
@@ -664,10 +664,10 @@ bool DRC::checkClearancePadToPad( D_PAD* aRefPad, D_PAD* aPad )
                 relativePadPos.x = ABS( relativePadPos.x );
                 relativePadPos.y = ABS( relativePadPos.y );
 
-                if( ( relativePadPos.x - ( (size.x + TO_LEGACY_LU( aRefPad->m_Size.x ) ) / 2 ) ) >= dist_min )
+                if( ( relativePadPos.x - ( (size.x + TO_LEGACY_LU( aRefPad->m_Size.x() ) ) / 2 ) ) >= dist_min )
                     diag = true;
 
-                if( ( relativePadPos.y - ( (size.y + TO_LEGACY_LU( aRefPad->m_Size.y) ) / 2 ) ) >= dist_min )
+                if( ( relativePadPos.y - ( (size.y + TO_LEGACY_LU( aRefPad->m_Size.y() ) ) / 2 ) ) >= dist_min )
                     diag = true;
             }
             else    // at least one pad has any other orient. Test is more tricky
@@ -716,15 +716,15 @@ bool DRC::checkClearancePadToPad( D_PAD* aRefPad, D_PAD* aPad )
         int segm_width;
         m_segmAngle = aRefPad->m_Orient;                // Segment orient.
 
-        if( aRefPad->m_Size.y < aRefPad->m_Size.x )     // Build an horizontal equiv segment
+        if( aRefPad->m_Size.y() < aRefPad->m_Size.x() )     // Build an horizontal equiv segment
         {
-            segm_width   = TO_LEGACY_LU( aRefPad->m_Size.y );
-            m_segmLength = TO_LEGACY_LU( aRefPad->m_Size.x - aRefPad->m_Size.y );
+            segm_width   = TO_LEGACY_LU( aRefPad->m_Size.y() );
+            m_segmLength = TO_LEGACY_LU( aRefPad->m_Size.x() - aRefPad->m_Size.y() );
         }
         else        // Vertical oval: build an horizontal equiv segment and rotate 90.0 deg
         {
-            segm_width   = TO_LEGACY_LU( aRefPad->m_Size.x );
-            m_segmLength = TO_LEGACY_LU( aRefPad->m_Size.y - aRefPad->m_Size.x );
+            segm_width   = TO_LEGACY_LU( aRefPad->m_Size.x() );
+            m_segmLength = TO_LEGACY_LU( aRefPad->m_Size.y() - aRefPad->m_Size.x() );
             m_segmAngle += 900;
         }
 
@@ -796,13 +796,13 @@ bool DRC::checkClearanceSegmToPad( const D_PAD* aPad, int aSegmentWidth, int aMi
     int     segmHalfWidth = aSegmentWidth / 2;
 
     seuil = segmHalfWidth + aMinDist;
-    padHalfsize.x = TO_LEGACY_LU( aPad->m_Size.x / 2 );
-    padHalfsize.y = TO_LEGACY_LU( aPad->m_Size.y / 2 );
+    padHalfsize.x = TO_LEGACY_LU( aPad->m_Size.x() / 2 );
+    padHalfsize.y = TO_LEGACY_LU( aPad->m_Size.y() / 2 );
 
     if( aPad->m_PadShape == PAD_TRAPEZOID ) // The size is bigger, due to m_DeltaSize extra size
     {
-        padHalfsize.x += TO_LEGACY_LU( ABS(aPad->m_DeltaSize.y) / 2 );   // Remember: m_DeltaSize.y is the m_Size.x change
-        padHalfsize.y += TO_LEGACY_LU( ABS(aPad->m_DeltaSize.x) / 2 );   // Remember: m_DeltaSize.x is the m_Size.y change
+        padHalfsize.x += TO_LEGACY_LU( abs( aPad->m_DeltaSize.y() ) / 2 );   // Remember: m_DeltaSize.y is the m_Size.x change
+        padHalfsize.y += TO_LEGACY_LU( abs( aPad->m_DeltaSize.x() ) / 2 );   // Remember: m_DeltaSize.x is the m_Size.y change
     }
 
     if( aPad->m_PadShape == PAD_CIRCLE )

pcbnew/editmod.cpp

@@ -82,7 +82,7 @@ void FOOTPRINT_EDIT_FRAME::Place_Ancre( MODULE* pt_mod )
 
     for( ; pt_pad != NULL; pt_pad = pt_pad->Next() )
     {
-        pt_pad->m_Pos0 += VECTOR_PCB( FROM_LEGACY_LU( moveVector.x ), FROM_LEGACY_LU( moveVector.y ) );
+        pt_pad->m_Pos0 += VECTOR_PCB::fromXY( FROM_LEGACY_LU( moveVector.x ), FROM_LEGACY_LU( moveVector.y ) );
     }
 
     /* Update the draw element coordinates. */

pcbnew/export_gencad.cpp

@@ -252,70 +252,70 @@ void CreatePadsShapesSection( FILE* file, BOARD* pcb )
 
         fprintf( file, "PAD PAD%d", pad->GetSubRatsnest() );
 
-        int dx = TO_LEGACY_LU( pad->m_Size.x / 2 );
-        int dy = TO_LEGACY_LU( pad->m_Size.y / 2 );
+        int dx = TO_LEGACY_LU( pad->m_Size.x() / 2 );
+        int dy = TO_LEGACY_LU( pad->m_Size.y() / 2 );
 
         switch( pad->m_PadShape )
         {
         default:
         case PAD_CIRCLE:
             pad_type = "ROUND";                   // how about oval holes?
-            fprintf( file, " %s %d\n", pad_type, ( int )TO_LEGACY_LU( pad->m_Drill.x ) );
+            fprintf( file, " %s %d\n", pad_type, ( int )TO_LEGACY_LU( pad->m_Drill.x() ) );
             fprintf( file, "CIRCLE %d %d %d\n",
-                     TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ), dx );
+                     TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ), dx );
             break;
 
         case PAD_RECT:
             pad_type = "RECTANGULAR";
-            fprintf( file, " %s %d\n", pad_type, ( int )TO_LEGACY_LU( pad->m_Drill.x ) );
+            fprintf( file, " %s %d\n", pad_type, ( int )TO_LEGACY_LU( pad->m_Drill.x() ) );
             fprintf( file, "RECTANGLE %d %d %d %d\n",
-                     TO_LEGACY_LU( pad->m_Offset.x ) - dx, -TO_LEGACY_LU( pad->m_Offset.y ) - dy,
-                     TO_LEGACY_LU( pad->m_Size.x ), TO_LEGACY_LU( pad->m_Size.y ) );
+                     TO_LEGACY_LU( pad->m_Offset.x() ) - dx, -TO_LEGACY_LU( pad->m_Offset.y() ) - dy,
+                     TO_LEGACY_LU( pad->m_Size.x() ), TO_LEGACY_LU( pad->m_Size.y() ) );
             break;
 
         case PAD_OVAL:     /* Create outline by 2 lines and 2 arcs */
         {
             pad_type = "FINGER";
-            fprintf( file, " %s %d\n", pad_type, ( int )TO_LEGACY_LU( pad->m_Drill.x ) );
+            fprintf( file, " %s %d\n", pad_type, ( int )TO_LEGACY_LU( pad->m_Drill.x() ) );
             int dr = dx - dy;
             if( dr >= 0 )       // Horizontal oval
             {
                 int radius = dy;
                 fprintf( file, "LINE %d %d %d %d\n",
-                         -dr + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) - radius,
-                         dr + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) - radius );
+                         -dr + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) - radius,
+                         dr + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) - radius );
                 fprintf( file, "ARC %d %d %d %d %d %d\n",
-                         dr + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) - radius,
-                         dr + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) + radius,
-                         dr + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) );
+                         dr + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) - radius,
+                         dr + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) + radius,
+                         dr + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) );
 
                 fprintf( file, "LINE %d %d %d %d\n",
-                         dr + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) + radius,
-                         -dr + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) + radius );
+                         dr + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) + radius,
+                         -dr + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) + radius );
                 fprintf( file, "ARC %d %d %d %d %d %d\n",
-                         -dr + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) + radius,
-                         -dr + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) - radius,
-                         -dr + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) );
+                         -dr + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) + radius,
+                         -dr + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) - radius,
+                         -dr + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) );
             }
             else        // Vertical oval
             {
                 dr = -dr;
                 int radius = dx;
                 fprintf( file, "LINE %d %d %d %d\n",
-                         -radius + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) - dr,
-                         -radius + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) + dr );
+                         -radius + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) - dr,
+                         -radius + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) + dr );
                 fprintf( file, "ARC %d %d %d %d %d %d\n",
-                         -radius + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) + dr,
-                         radius + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) + dr,
-                         TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) + dr );
+                         -radius + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) + dr,
+                         radius + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) + dr,
+                         TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) + dr );
 
                 fprintf( file, "LINE %d %d %d %d\n",
-                         radius + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) + dr,
-                         radius + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) - dr );
+                         radius + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) + dr,
+                         radius + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) - dr );
                 fprintf( file, "ARC %d %d %d %d %d %d\n",
-                         radius + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) - dr,
-                         -radius + TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) - dr,
-                         TO_LEGACY_LU( pad->m_Offset.x ), -TO_LEGACY_LU( pad->m_Offset.y ) - dr );
+                         radius + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) - dr,
+                         -radius + TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) - dr,
+                         TO_LEGACY_LU( pad->m_Offset.x() ), -TO_LEGACY_LU( pad->m_Offset.y() ) - dr );
             }
             break;
         }
@@ -410,7 +410,7 @@ void CreateShapesSection( FILE* file, BOARD* pcb )
             NORMALIZE_ANGLE_POS( orient );
             fprintf( file, "PIN %s PAD%d %d %d %s %d %s",
                      TO_UTF8( pinname ), pad->GetSubRatsnest(),
-                     TO_LEGACY_LU( pad->m_Pos0.x ), TO_LEGACY_LU( -pad->m_Pos0.y ),
+                     TO_LEGACY_LU( pad->m_Pos0.x() ), TO_LEGACY_LU( -pad->m_Pos0.y() ),
                      layer, orient / 10, mirror );
 
             if( orient % 10 )

pcbnew/export_vrml.cpp

@@ -881,8 +881,8 @@ static void export_vrml_edge_module( EDGE_MODULE* module ) /*{{{*/
 
 static void export_vrml_pad( BOARD* pcb, D_PAD* pad ) /*{{{*/
 {
-    double hole_drill_w = (double) TO_LEGACY_LU_DBL( pad->m_Drill.x / 2 );
-    double hole_drill_h = (double) TO_LEGACY_LU_DBL( pad->m_Drill.y / 2 );
+    double hole_drill_w = (double) TO_LEGACY_LU_DBL( pad->m_Drill.x() / 2 );
+    double hole_drill_h = (double) TO_LEGACY_LU_DBL( pad->m_Drill.y() / 2 );
     double hole_drill   = MIN( hole_drill_w, hole_drill_h );
     double hole_x = pad->m_Pos.x;
     double hole_y = pad->m_Pos.y;
@@ -916,8 +916,8 @@ static void export_vrml_pad( BOARD* pcb, D_PAD* pad ) /*{{{*/
     wxSize        pad_delta = TO_LEGACY_LU_WXS( pad->m_DeltaSize );
     double        pad_dx    = pad_delta.x / 2;
     double        pad_dy    = pad_delta.y / 2;
-    double        pad_w     = TO_LEGACY_LU_DBL( pad->m_Size.x / 2 );
-    double        pad_h     = TO_LEGACY_LU_DBL( pad->m_Size.y / 2 );
+    double        pad_w     = TO_LEGACY_LU_DBL( pad->m_Size.x() / 2 );
+    double        pad_h     = TO_LEGACY_LU_DBL( pad->m_Size.y() / 2 );
 
     for( int layer = FIRST_COPPER_LAYER; layer < copper_layers; layer++ )
     {

pcbnew/gen_holes_and_tools_lists_for_drill.cpp

@@ -127,21 +127,21 @@ void Build_Holes_List( BOARD* aPcb,
                 if( aGenerateNPTH_list && pad->m_Attribut != PAD_HOLE_NOT_PLATED )
                     continue;
 
-                if( pad->m_Drill.x == ZERO_LENGTH )
+                if( pad->m_Drill.x() == ZERO_LENGTH )
                     continue;
 
                 new_hole.m_Hole_NotPlated = (pad->m_Attribut == PAD_HOLE_NOT_PLATED);
                 new_hole.m_Tool_Reference = -1;         // Flag is: Not initialized
                 new_hole.m_Hole_Orient    = pad->m_Orient;
                 new_hole.m_Hole_Shape    = 0;           // hole shape: round
-                new_hole.m_Hole_Diameter = min( TO_LEGACY_LU( pad->m_Drill.x ), TO_LEGACY_LU( pad->m_Drill.y ) );
+                new_hole.m_Hole_Diameter = min( TO_LEGACY_LU( pad->m_Drill.x() ), TO_LEGACY_LU( pad->m_Drill.y() ) );
                 new_hole.m_Hole_Size.x    = new_hole.m_Hole_Size.y = new_hole.m_Hole_Diameter;
 
                 if( pad->m_DrillShape != PAD_CIRCLE )
                     new_hole.m_Hole_Shape = 1; // oval flag set
 
-                new_hole.m_Hole_Size.x = TO_LEGACY_LU( pad->m_Drill.x );
-                new_hole.m_Hole_Size.y = TO_LEGACY_LU( pad->m_Drill.y );
+                new_hole.m_Hole_Size.x = TO_LEGACY_LU( pad->m_Drill.x() );
+                new_hole.m_Hole_Size.y = TO_LEGACY_LU( pad->m_Drill.y() );
                 new_hole.m_Hole_Pos = pad->m_Pos;               // hole position
                 new_hole.m_Hole_Bottom_Layer = LAYER_N_BACK;
                 new_hole.m_Hole_Top_Layer    = LAYER_N_FRONT;// pad holes are through holes

pcbnew/gen_modules_placefile.cpp

@@ -438,19 +438,20 @@ void PCB_EDIT_FRAME::GenModuleReport( wxCommandEvent& event )
         {
             fprintf( rptfile, "$PAD \"%.4s\"\n", pad->m_Padname );
             sprintf( line, "position %9.6f %9.6f\n",
-                     TO_LEGACY_LU_DBL( pad->m_Pos0.x ) * conv_unit,
-                     TO_LEGACY_LU_DBL( pad->m_Pos0.y ) * conv_unit );
+                     TO_LEGACY_LU_DBL( pad->m_Pos0.x() ) * conv_unit,
+                     TO_LEGACY_LU_DBL( pad->m_Pos0.y() ) * conv_unit );
             fputs( line, rptfile );
 
             sprintf( line, "size %9.6f %9.6f\n",
-                     TO_LEGACY_LU_DBL( pad->m_Size.x ) * conv_unit,
-                     TO_LEGACY_LU_DBL( pad->m_Size.y ) * conv_unit );
+                     TO_LEGACY_LU_DBL( pad->m_Size.x() ) * conv_unit,
+                     TO_LEGACY_LU_DBL( pad->m_Size.y() ) * conv_unit );
             fputs( line, rptfile );
-            sprintf( line, "drill %9.6f\n", TO_LEGACY_LU_DBL( pad->m_Drill.x ) * conv_unit );
+            sprintf( line, "drill %9.6f\n",
+                     TO_LEGACY_LU_DBL( pad->m_Drill.x() ) * conv_unit );
             fputs( line, rptfile );
             sprintf( line, "shape_offset %9.6f %9.6f\n",
-                     TO_LEGACY_LU_DBL( pad->m_Offset.x ) * conv_unit,
-                     TO_LEGACY_LU_DBL( pad->m_Offset.y ) * conv_unit );
+                     TO_LEGACY_LU_DBL( pad->m_Offset.x() ) * conv_unit,
+                     TO_LEGACY_LU_DBL( pad->m_Offset.y() ) * conv_unit );
             fputs( line, rptfile );
 
             sprintf( line, "orientation  %.2f\n",

pcbnew/globaleditpad.cpp

@@ -254,19 +254,19 @@ void PCB_BASE_FRAME::Global_Import_Pad_Settings( D_PAD* aPad, bool aDraw )
 
             if( pt_pad->m_PadShape != PAD_TRAPEZOID )
             {
-                pt_pad->m_DeltaSize.x = ZERO_LENGTH;
-                pt_pad->m_DeltaSize.y = ZERO_LENGTH;
+                pt_pad->m_DeltaSize.x() = ZERO_LENGTH;
+                pt_pad->m_DeltaSize.y() = ZERO_LENGTH;
             }
             if( pt_pad->m_PadShape == PAD_CIRCLE )
-                pt_pad->m_Size.y = pt_pad->m_Size.x;
+                pt_pad->m_Size.y() = pt_pad->m_Size.x();
 
             switch( pt_pad->m_Attribut & 0x7F )
             {
             case PAD_SMD:
             case PAD_CONN:
-                pt_pad->m_Drill    = VECTOR_PCB(ZERO_LENGTH, ZERO_LENGTH);//wxSize( 0, 0 );
-                pt_pad->m_Offset.x = ZERO_LENGTH;
-                pt_pad->m_Offset.y = ZERO_LENGTH;
+                pt_pad->m_Drill      = VECTOR_PCB::fromXY(ZERO_LENGTH, ZERO_LENGTH);//wxSize( 0, 0 );
+                pt_pad->m_Offset.x() = ZERO_LENGTH;
+                pt_pad->m_Offset.y() = ZERO_LENGTH;
                 break;
 
             default:

pcbnew/gpcb_exchange.cpp

@@ -369,16 +369,16 @@ bool MODULE::Read_GPCB_Descr( const wxString& CmpFullFileName )
             {
                 Pad->SetPadName( params[10] );
             }
-            Pad->m_Pos.x  = (ibuf[0] + ibuf[2]) / 2;
-            Pad->m_Pos.y  = (ibuf[1] + ibuf[3]) / 2;
-            Pad->m_Size.x = FROM_LEGACY_LU( ibuf[4] + abs( ibuf[0] - ibuf[2] ) );
-            Pad->m_Size.y = FROM_LEGACY_LU( ibuf[4] + abs( ibuf[1] - ibuf[3] ) );
-            Pad->m_Pos.x += m_Pos.x;
-            Pad->m_Pos.y += m_Pos.y;
+            Pad->m_Pos.x    = (ibuf[0] + ibuf[2]) / 2;
+            Pad->m_Pos.y    = (ibuf[1] + ibuf[3]) / 2;
+            Pad->m_Size.x() = FROM_LEGACY_LU( ibuf[4] + abs( ibuf[0] - ibuf[2] ) );
+            Pad->m_Size.y() = FROM_LEGACY_LU( ibuf[4] + abs( ibuf[1] - ibuf[3] ) );
+            Pad->m_Pos.x   += m_Pos.x;
+            Pad->m_Pos.y   += m_Pos.y;
 
             if( !TestFlags( params[iflgidx], 0x0100, wxT( "square" ) ) )
             {
-                if( Pad->m_Size.x == Pad->m_Size.y )
+                if( Pad->m_Size.x() == Pad->m_Size.y() )
                     Pad->m_PadShape = PAD_ROUND;
                 else
                     Pad->m_PadShape = PAD_OVAL;
@@ -430,12 +430,13 @@ bool MODULE::Read_GPCB_Descr( const wxString& CmpFullFileName )
 
             Pad->m_Pos.x   = ibuf[0];
             Pad->m_Pos.y   = ibuf[1];
-            Pad->m_Drill.x = Pad->m_Drill.y = FROM_LEGACY_LU( (int) ibuf[5] );
-            Pad->m_Size.x  = Pad->m_Size.y = FROM_LEGACY_LU( ibuf[3] ) + Pad->m_Drill.x;
+            Pad->m_Drill.x() = Pad->m_Drill.y() = FROM_LEGACY_LU( (int) ibuf[5] );
+            Pad->m_Size.x()  = Pad->m_Size.y()  =
+                                FROM_LEGACY_LU( ibuf[3] ) + Pad->m_Drill.x();
             Pad->m_Pos.x  += m_Pos.x;
             Pad->m_Pos.y  += m_Pos.y;
 
-            if( (Pad->m_PadShape == PAD_ROUND) && (Pad->m_Size.x != Pad->m_Size.y) )
+            if( (Pad->m_PadShape == PAD_ROUND) && (Pad->m_Size.x() != Pad->m_Size.y()) )
                 Pad->m_PadShape = PAD_OVAL;
 
             m_Pads.PushBack( Pad );

pcbnew/graphpcb.cpp

@@ -89,7 +89,7 @@ void PlacePad( BOARD* Pcb, D_PAD* pt_pad, int color, int marge, int op_logic )
     int     dx, dy;
     wxPoint shape_pos = pt_pad->ReturnShapePos();
 
-    dx = TO_LEGACY_LU( pt_pad->m_Size.x / 2 );
+    dx = TO_LEGACY_LU( pt_pad->m_Size.x() / 2 );
     dx += marge;
 
     if( pt_pad->m_PadShape == PAD_CIRCLE )
@@ -100,13 +100,13 @@ void PlacePad( BOARD* Pcb, D_PAD* pt_pad, int color, int marge, int op_logic )
     }
 
 
-    dy = TO_LEGACY_LU( pt_pad->m_Size.y / 2 );
+    dy = TO_LEGACY_LU( pt_pad->m_Size.y() / 2 );
     dy += marge;
 
     if( pt_pad->m_PadShape == PAD_TRAPEZOID )
     {
-        dx += TO_LEGACY_LU( ABS( pt_pad->m_DeltaSize.y ) / 2 );
-        dy += TO_LEGACY_LU( ABS( pt_pad->m_DeltaSize.x ) / 2 );
+        dx += TO_LEGACY_LU( abs( pt_pad->m_DeltaSize.y() ) / 2 );
+        dy += TO_LEGACY_LU( abs( pt_pad->m_DeltaSize.x() ) / 2 );
     }
 
     if( ( pt_pad->m_Orient % 900 ) == 0 ) /* The pad is a rectangle

pcbnew/ioascii.cpp

@@ -586,16 +586,16 @@ int PCB_BASE_FRAME::ReadSetup( LINE_READER* aReader )
 
         if( stricmp( line, "PadSize" ) == 0 )
         {
-            g_Pad_Master.m_Size.x = LENGTH_LOAD_STR( data );
+            g_Pad_Master.m_Size.x() = LENGTH_LOAD_STR( data );
             data = strtok( NULL, delims );
-            g_Pad_Master.m_Size.y = LENGTH_LOAD_STR( data );
+            g_Pad_Master.m_Size.y() = LENGTH_LOAD_STR( data );
             continue;
         }
 
         if( stricmp( line, "PadDrill" ) == 0 )
         {
-            g_Pad_Master.m_Drill.x = LENGTH_LOAD_STR( data );
-            g_Pad_Master.m_Drill.y = g_Pad_Master.m_Drill.x;
+            g_Pad_Master.m_Drill.x() = LENGTH_LOAD_STR( data );
+            g_Pad_Master.m_Drill.y() = g_Pad_Master.m_Drill.x();
             continue;
         }
 
@@ -757,8 +757,8 @@ static int WriteSetup( FILE* aFile, PCB_EDIT_FRAME* aFrame, BOARD* aBoard )
     fprintf( aFile, "EdgeModWidth %d\n", g_ModuleSegmentWidth );
     fprintf( aFile, "TextModSize %d %d\n", g_ModuleTextSize.x, g_ModuleTextSize.y );
     fprintf( aFile, "TextModWidth %d\n", g_ModuleTextWidth );
-    fprintf( aFile, "PadSize "FM_LENSV" "FM_LENSV"\n", ARG_LENSV( g_Pad_Master.m_Size.x ), ARG_LENSV( g_Pad_Master.m_Size.y ) );
-    fprintf( aFile, "PadDrill "FM_LENSV"\n", ARG_LENSV( g_Pad_Master.m_Drill.x ) );
+    fprintf( aFile, "PadSize "FM_LENSV" "FM_LENSV"\n", ARG_LENSV( g_Pad_Master.m_Size.x() ), ARG_LENSV( g_Pad_Master.m_Size.y() ) );
+    fprintf( aFile, "PadDrill "FM_LENSV"\n", ARG_LENSV( g_Pad_Master.m_Drill.x() ) );
     fprintf( aFile,
              "Pad2MaskClearance %d\n",
              aBoard->GetBoardDesignSettings()->m_SolderMaskMargin );

pcbnew/modedit.cpp

@@ -711,15 +711,15 @@ void FOOTPRINT_EDIT_FRAME::Transform( MODULE* module, int transform )
             pad->m_Pos0    = FROM_LEGACY_LU_VEC( pad->m_Pos );
             pad->m_Orient -= angle;
             wxPoint of;
-            of.x = TO_LEGACY_LU( pad->m_Offset.x );
-            of.y = TO_LEGACY_LU( pad->m_Offset.y );
+            of.x = TO_LEGACY_LU( pad->m_Offset.x() );
+            of.y = TO_LEGACY_LU( pad->m_Offset.y() );
             RotatePoint( &of.x, &of.y, angle );
-            pad->m_Offset.x = FROM_LEGACY_LU( of.x );
-            pad->m_Offset.y = FROM_LEGACY_LU( of.y );
-            EXCHG( pad->m_Size.x, pad->m_Size.y );
+            pad->m_Offset.x() = FROM_LEGACY_LU( of.x );
+            pad->m_Offset.y() = FROM_LEGACY_LU( of.y );
+            EXCHG( pad->m_Size.x(), pad->m_Size.y() );
 	    wxSize delta = TO_LEGACY_LU_WXS( pad->m_DeltaSize );
             RotatePoint( &delta.x, &delta.y, -angle );
-	    pad->m_DeltaSize = VECTOR_PCB( FROM_LEGACY_LU( delta.x ), FROM_LEGACY_LU( delta.y ) );
+	    pad->m_DeltaSize = VECTOR_PCB::fromXY( FROM_LEGACY_LU( delta.x ), FROM_LEGACY_LU( delta.y ) );
         }
 
         module->m_Reference->m_Pos0    = module->m_Reference->m_Pos;
@@ -757,9 +757,9 @@ void FOOTPRINT_EDIT_FRAME::Transform( MODULE* module, int transform )
         for( ; pad != NULL; pad = (D_PAD*) pad->Next() )
         {
             NEGATE( pad->m_Pos.y );
-            NEGATE( pad->m_Pos0.y );
-            NEGATE( pad->m_Offset.y );
-            NEGATE( pad->m_DeltaSize.y );
+            NEGATE( pad->m_Pos0.y() );
+            NEGATE( pad->m_Offset.y() );
+            NEGATE( pad->m_DeltaSize.y() );
 
             if( pad->m_Orient )
                 pad->m_Orient = 3600 - pad->m_Orient;

pcbnew/move-drag_pads.cpp

@@ -148,7 +148,7 @@ void PCB_BASE_FRAME::Import_Pad_Settings( D_PAD* aPad, bool aDraw )
     aPad->m_Orient = g_Pad_Master.m_Orient +
                      ( (MODULE*) aPad->GetParent() )->m_Orient;
     aPad->m_Size = g_Pad_Master.m_Size;
-    aPad->m_DeltaSize  = VECTOR_PCB( ZERO_LENGTH, ZERO_LENGTH );//wxSize( 0, 0 );
+    aPad->m_DeltaSize  = VECTOR_PCB::fromXY( ZERO_LENGTH, ZERO_LENGTH );//wxSize( 0, 0 );
     aPad->m_Offset     = g_Pad_Master.m_Offset;
     aPad->m_Drill      = g_Pad_Master.m_Drill;
     aPad->m_DrillShape = g_Pad_Master.m_DrillShape;
@@ -160,7 +160,7 @@ void PCB_BASE_FRAME::Import_Pad_Settings( D_PAD* aPad, bool aDraw )
         break;
 
     case PAD_CIRCLE:
-        aPad->m_Size.y = aPad->m_Size.x;
+        aPad->m_Size.y() = aPad->m_Size.x();
         break;
     }
 
@@ -168,8 +168,8 @@ void PCB_BASE_FRAME::Import_Pad_Settings( D_PAD* aPad, bool aDraw )
     {
     case PAD_SMD:
     case PAD_CONN:
-        aPad->m_Drill    = VECTOR_PCB( ZERO_LENGTH, ZERO_LENGTH ); //wxSize( 0, 0 );
-        aPad->m_Offset   = VECTOR_PCB( ZERO_LENGTH, ZERO_LENGTH );
+        aPad->m_Drill    = VECTOR_PCB::fromXY( ZERO_LENGTH, ZERO_LENGTH ); //wxSize( 0, 0 );
+        aPad->m_Offset   = VECTOR_PCB::fromXY( ZERO_LENGTH, ZERO_LENGTH );
     }
 
     aPad->ComputeShapeMaxRadius();
@@ -366,8 +366,8 @@ void PCB_BASE_FRAME::PlacePad( D_PAD* Pad, wxDC* DC )
     dY = Pad->m_Pos.y - Pad_OldPos.y;
     RotatePoint( &dX, &dY, -Module->m_Orient );
 
-    Pad->m_Pos0.x += FROM_LEGACY_LU( dX );
-    s_CurrentSelectedPad->m_Pos0.y += FROM_LEGACY_LU( dY ); /// @BUG???
+    Pad->m_Pos0.x() += FROM_LEGACY_LU( dX );
+    s_CurrentSelectedPad->m_Pos0.y() += FROM_LEGACY_LU( dY ); /// @BUG???
 
     Pad->m_Flags = 0;
 
@@ -402,13 +402,13 @@ void PCB_BASE_FRAME::RotatePad( D_PAD* Pad, wxDC* DC )
     if( DC )
         Module->Draw( DrawPanel, DC, GR_XOR );
 
-    EXCHG( Pad->m_Size.x, Pad->m_Size.y );
-    EXCHG( Pad->m_Drill.x, Pad->m_Drill.y );
-    EXCHG( Pad->m_Offset.x, Pad->m_Offset.y );
-    Pad->m_Offset.y = -Pad->m_Offset.y;
+    EXCHG( Pad->m_Size.x(), Pad->m_Size.y() );
+    EXCHG( Pad->m_Drill.x(), Pad->m_Drill.y() );
+    EXCHG( Pad->m_Offset.x(), Pad->m_Offset.y() );
+    Pad->m_Offset.y() = -Pad->m_Offset.y();
 
-    EXCHG( Pad->m_DeltaSize.x, Pad->m_DeltaSize.y );
-    Pad->m_DeltaSize.x = -Pad->m_DeltaSize.x;
+    EXCHG( Pad->m_DeltaSize.x(), Pad->m_DeltaSize.y() );
+    Pad->m_DeltaSize.x() = -Pad->m_DeltaSize.x();
     Module->CalculateBoundingBox();
     Pad->DisplayInfo( this );
 

pcbnew/muonde.cpp

@@ -260,10 +260,10 @@ MODULE* PCB_EDIT_FRAME::Genere_Self( wxDC* DC )
     Module->m_Pads.PushFront( PtPad );
 
     PtPad->SetPadName( wxT( "1" ) );
-    PtPad->m_Pos    = Mself.m_End;
-    PtPad->m_Pos0   = FROM_LEGACY_LU_VEC( PtPad->m_Pos - Module->m_Pos );
-    PtPad->m_Size.x = PtPad->m_Size.y = FROM_LEGACY_LU( Mself.m_Width );
-    PtPad->m_layerMask = g_TabOneLayerMask[Module->GetLayer()];
+    PtPad->m_Pos          = Mself.m_End;
+    PtPad->m_Pos0         = FROM_LEGACY_LU_VEC( PtPad->m_Pos - Module->m_Pos );
+    PtPad->m_Size.x()     = PtPad->m_Size.y() = FROM_LEGACY_LU( Mself.m_Width );
+    PtPad->m_layerMask    = g_TabOneLayerMask[Module->GetLayer()];
     PtPad->m_Attribut     = PAD_SMD;
     PtPad->m_PadShape     = PAD_CIRCLE;
     PtPad->ComputeShapeMaxRadius();
@@ -552,7 +552,7 @@ MODULE* PCB_EDIT_FRAME::Create_MuWaveBasicShape( const wxString& name, int pad_c
 
         Module->m_Pads.PushFront( pad );
 
-        pad->m_Size.x    = pad->m_Size.y = FROM_LEGACY_LU( GetBoard()->GetCurrentTrackWidth() );
+        pad->m_Size.x()  = pad->m_Size.y() = FROM_LEGACY_LU( GetBoard()->GetCurrentTrackWidth() );
         pad->m_Pos       = Module->m_Pos;
         pad->m_PadShape  = PAD_RECT;
         pad->m_Attribut  = PAD_SMD;
@@ -656,19 +656,19 @@ MODULE* PCB_EDIT_FRAME::Create_MuWaveComponent( int shape_type )
     switch( shape_type )
     {
     case 0:     //Gap :
-        pad->m_Pos0.x = FROM_LEGACY_LU( oX = -( gap_size + TO_LEGACY_LU( pad->m_Size.x ) ) / 2 );
-        pad->m_Pos.x += TO_LEGACY_LU( pad->m_Pos0.x );
+        pad->m_Pos0.x() = FROM_LEGACY_LU( oX = -( gap_size + TO_LEGACY_LU( pad->m_Size.x() ) ) / 2 );
+        pad->m_Pos.x += TO_LEGACY_LU( pad->m_Pos0.x() );
         pad = pad->Next();
-        pad->m_Pos0.x = FROM_LEGACY_LU( oX + gap_size + TO_LEGACY_LU( pad->m_Size.x ) );
-        pad->m_Pos.x += TO_LEGACY_LU( pad->m_Pos0.x );
+        pad->m_Pos0.x() = FROM_LEGACY_LU( oX + gap_size + TO_LEGACY_LU( pad->m_Size.x() ) );
+        pad->m_Pos.x += TO_LEGACY_LU( pad->m_Pos0.x() );
         break;
 
     case 1:     //Stub :
         pad->SetPadName( wxT( "1" ) );
         pad = pad->Next();
-        pad->m_Pos0.y = FROM_LEGACY_LU( -( gap_size + TO_LEGACY_LU( pad->m_Size.y ) ) / 2 );
-        pad->m_Size.y = FROM_LEGACY_LU( gap_size );
-        pad->m_Pos.y += TO_LEGACY_LU( pad->m_Pos0.y );
+        pad->m_Pos0.y() = FROM_LEGACY_LU( -( gap_size + TO_LEGACY_LU( pad->m_Size.y() ) ) / 2 );
+        pad->m_Size.y() = FROM_LEGACY_LU( gap_size );
+        pad->m_Pos.y   += TO_LEGACY_LU( pad->m_Pos0.y() );
         break;
 
     case 2:     // Arc Stub created by a polygonal approach:
@@ -683,7 +683,7 @@ MODULE* PCB_EDIT_FRAME::Create_MuWaveComponent( int shape_type )
         std::vector<wxPoint> polyPoints = edge->GetPolyPoints();
         polyPoints.reserve( numPoints );
 
-        edge->m_Start0.y = TO_LEGACY_LU( -pad->m_Size.y / 2 );
+        edge->m_Start0.y = TO_LEGACY_LU( -pad->m_Size.y() / 2 );
 
         polyPoints.push_back( wxPoint( 0, 0 ) );
 
@@ -968,12 +968,12 @@ MODULE* PCB_EDIT_FRAME::Create_MuWavePolygonShape()
     Module = Create_MuWaveBasicShape( cmp_name, pad_count );
     pad1   = Module->m_Pads;
 
-    pad1->m_Pos0.x = FROM_LEGACY_LU( -ShapeSize.x / 2 );
-    pad1->m_Pos.x += TO_LEGACY_LU( pad1->m_Pos0.x );
+    pad1->m_Pos0.x() = FROM_LEGACY_LU( -ShapeSize.x / 2 );
+    pad1->m_Pos.x += TO_LEGACY_LU( pad1->m_Pos0.x() );
 
     pad2 = (D_PAD*) pad1->Next();
-    pad2->m_Pos0.x = pad1->m_Pos0.x + FROM_LEGACY_LU( ShapeSize.x );
-    pad2->m_Pos.x += TO_LEGACY_LU( pad2->m_Pos0.x );
+    pad2->m_Pos0.x() = pad1->m_Pos0.x() + FROM_LEGACY_LU( ShapeSize.x );
+    pad2->m_Pos.x += TO_LEGACY_LU( pad2->m_Pos0.x() );
 
     edge = new EDGE_MODULE( Module );
 
@@ -987,13 +987,13 @@ MODULE* PCB_EDIT_FRAME::Create_MuWavePolygonShape()
     polyPoints.reserve( 2 * PolyEdges.size() + 2 );
 
     // Init start point coord:
-    polyPoints.push_back( wxPoint( TO_LEGACY_LU( pad1->m_Pos0.x ), 0 ) );
+    polyPoints.push_back( wxPoint( TO_LEGACY_LU( pad1->m_Pos0.x() ), 0 ) );
 
     wxPoint first_coordinate, last_coordinate;
 
     for( ii = 0; ii < PolyEdges.size(); ii++ )  // Copy points
     {
-        last_coordinate.x = wxRound( PolyEdges[ii] * ShapeScaleX ) + TO_LEGACY_LU( pad1->m_Pos0.x );
+        last_coordinate.x = wxRound( PolyEdges[ii] * ShapeScaleX ) + TO_LEGACY_LU( pad1->m_Pos0.x() );
         last_coordinate.y = -wxRound( PolyEdges[ii] * ShapeScaleY );
         polyPoints.push_back( last_coordinate );
     }
@@ -1005,15 +1005,15 @@ MODULE* PCB_EDIT_FRAME::Create_MuWavePolygonShape()
     case 0:     // Single
     case 2:     // Single mirrored
         // Init end point coord:
-        pad2->m_Pos0.x = FROM_LEGACY_LU( last_coordinate.x );
+        pad2->m_Pos0.x() = FROM_LEGACY_LU( last_coordinate.x );
         polyPoints.push_back( wxPoint( last_coordinate.x, 0 ) );
 
-        pad1->m_Size.x = pad1->m_Size.y = FROM_LEGACY_LU( ABS( first_coordinate.y ) );
-        pad2->m_Size.x = pad2->m_Size.y = FROM_LEGACY_LU( ABS( last_coordinate.y ) );
-        pad1->m_Pos0.y = FROM_LEGACY_LU( first_coordinate.y / 2 );
-        pad2->m_Pos0.y = FROM_LEGACY_LU( last_coordinate.y / 2 );
-        pad1->m_Pos.y  = TO_LEGACY_LU( pad1->m_Pos0.y ) + Module->m_Pos.y;
-        pad2->m_Pos.y  = TO_LEGACY_LU( pad2->m_Pos0.y ) + Module->m_Pos.y;
+        pad1->m_Size.x() = pad1->m_Size.y() = FROM_LEGACY_LU( abs( first_coordinate.y ) );
+        pad2->m_Size.x() = pad2->m_Size.y() = FROM_LEGACY_LU( abs( last_coordinate.y ) );
+        pad1->m_Pos0.y() = FROM_LEGACY_LU( first_coordinate.y / 2 );
+        pad2->m_Pos0.y() = FROM_LEGACY_LU( last_coordinate.y / 2 );
+        pad1->m_Pos.y  = TO_LEGACY_LU( pad1->m_Pos0.y() ) + Module->m_Pos.y;
+        pad2->m_Pos.y  = TO_LEGACY_LU( pad2->m_Pos0.y() ) + Module->m_Pos.y;
         break;
 
     case 1:     // Symmetric
@@ -1026,8 +1026,8 @@ MODULE* PCB_EDIT_FRAME::Create_MuWavePolygonShape()
             polyPoints.push_back( pt );
         }
 
-        pad1->m_Size.x = pad1->m_Size.y = FROM_LEGACY_LU( 2 * ABS( first_coordinate.y ) );
-        pad2->m_Size.x = pad2->m_Size.y = FROM_LEGACY_LU( 2 * ABS( last_coordinate.y ) );
+        pad1->m_Size.x() = pad1->m_Size.y() = FROM_LEGACY_LU( 2 * abs( first_coordinate.y ) );
+        pad2->m_Size.x() = pad2->m_Size.y() = FROM_LEGACY_LU( 2 * abs( last_coordinate.y ) );
         break;
     }
 
@@ -1073,7 +1073,7 @@ void PCB_EDIT_FRAME::Edit_Gap( wxDC* DC, MODULE* Module )
     Module->Draw( DrawPanel, DC, GR_XOR );
 
     /* Calculate the current dimension. */
-    gap_size = TO_LEGACY_LU( next_pad->m_Pos0.x - pad->m_Pos0.x - pad->m_Size.x );
+    gap_size = TO_LEGACY_LU( next_pad->m_Pos0.x() - pad->m_Pos0.x() - pad->m_Size.x() );
 
     /* Entrer the desired length of the gap. */
     msg = ReturnStringFromValue( g_UserUnit, gap_size, GetScreen()->GetInternalUnits() );
@@ -1086,19 +1086,19 @@ void PCB_EDIT_FRAME::Edit_Gap( wxDC* DC, MODULE* Module )
     gap_size = ReturnValueFromString( g_UserUnit, msg, GetScreen()->GetInternalUnits() );
 
     /* Updating sizes of pads forming the gap. */
-    pad->m_Size.x = pad->m_Size.y = FROM_LEGACY_LU( GetBoard()->GetCurrentTrackWidth() );
-    pad->m_Pos0.y = ZERO_LENGTH;
-    pad->m_Pos0.x = FROM_LEGACY_LU( oX = -( ( gap_size + TO_LEGACY_LU( pad->m_Size.x ) ) / 2 ) );
-    pad->m_Pos.x = TO_LEGACY_LU( pad->m_Pos0.x ) + Module->m_Pos.x;
-    pad->m_Pos.y = TO_LEGACY_LU( pad->m_Pos0.y ) + Module->m_Pos.y;
+    pad->m_Size.x() = pad->m_Size.y() = FROM_LEGACY_LU( GetBoard()->GetCurrentTrackWidth() );
+    pad->m_Pos0.y() = ZERO_LENGTH;
+    pad->m_Pos0.x() = FROM_LEGACY_LU( oX = -( ( gap_size + TO_LEGACY_LU( pad->m_Size.x() ) ) / 2 ) );
+    pad->m_Pos.x = TO_LEGACY_LU( pad->m_Pos0.x() ) + Module->m_Pos.x;
+    pad->m_Pos.y = TO_LEGACY_LU( pad->m_Pos0.y() ) + Module->m_Pos.y;
     RotatePoint( &pad->m_Pos.x, &pad->m_Pos.y,
                  Module->m_Pos.x, Module->m_Pos.y, Module->m_Orient );
 
-    next_pad->m_Size.x = next_pad->m_Size.y = FROM_LEGACY_LU( GetBoard()->GetCurrentTrackWidth() );
-    next_pad->m_Pos0.y = ZERO_LENGTH;
-    next_pad->m_Pos0.x = FROM_LEGACY_LU( oX + gap_size + TO_LEGACY_LU( next_pad->m_Size.x ) );
-    next_pad->m_Pos.x  = TO_LEGACY_LU( next_pad->m_Pos0.x ) + Module->m_Pos.x;
-    next_pad->m_Pos.y  = TO_LEGACY_LU( next_pad->m_Pos0.y ) + Module->m_Pos.y;
+    next_pad->m_Size.x() = next_pad->m_Size.y() = FROM_LEGACY_LU( GetBoard()->GetCurrentTrackWidth() );
+    next_pad->m_Pos0.y() = ZERO_LENGTH;
+    next_pad->m_Pos0.x() = FROM_LEGACY_LU( oX + gap_size + TO_LEGACY_LU( next_pad->m_Size.x() ) );
+    next_pad->m_Pos.x  = TO_LEGACY_LU( next_pad->m_Pos0.x() ) + Module->m_Pos.x;
+    next_pad->m_Pos.y  = TO_LEGACY_LU( next_pad->m_Pos0.y() ) + Module->m_Pos.y;
     RotatePoint( &next_pad->m_Pos.x, &next_pad->m_Pos.y,
                  Module->m_Pos.x, Module->m_Pos.y, Module->m_Orient );
 

pcbnew/plot_rtn.cpp

@@ -97,7 +97,7 @@ void PCB_BASE_FRAME::PlotSilkScreen( PLOTTER* plotter, int aLayerMask, GRTraceMo
                 switch( pad->m_PadShape & 0x7F )
                 {
                 case PAD_CIRCLE:
-                    plotter->flash_pad_circle( shape_pos, TO_LEGACY_LU( pad->m_Size.x ), FILAIRE );
+                    plotter->flash_pad_circle( shape_pos, TO_LEGACY_LU( pad->m_Size.x() ), FILAIRE );
                     break;
 
                 case PAD_OVAL:
@@ -840,8 +840,8 @@ void PCB_BASE_FRAME::Plot_Standard_Layer( PLOTTER*    aPlotter,
                 break;
             }
 
-            size.x = TO_LEGACY_LU( pad->m_Size.x ) + ( 2 * margin.x );
-            size.y = TO_LEGACY_LU( pad->m_Size.y ) + ( 2 * margin.y );
+            size.x = TO_LEGACY_LU( pad->m_Size.x() ) + ( 2 * margin.x );
+            size.y = TO_LEGACY_LU( pad->m_Size.y() ) + ( 2 * margin.y );
 
             /* Don't draw a null size item : */
             if( size.x <= 0 || size.y <= 0 )
@@ -851,8 +851,8 @@ void PCB_BASE_FRAME::Plot_Standard_Layer( PLOTTER*    aPlotter,
             {
             case PAD_CIRCLE:
                 if( aSkipNPTH_Pads &&
-                    ( pad->m_Size.x == pad->m_Drill.x ) &&
-                    ( pad->m_Size.y == pad->m_Drill.y ) &&
+                    ( pad->m_Size.x() == pad->m_Drill.x() ) &&
+                    ( pad->m_Size.y() == pad->m_Drill.y() ) &&
                     (pad->m_Attribut == PAD_HOLE_NOT_PLATED) )
                     break;
 
@@ -861,8 +861,8 @@ void PCB_BASE_FRAME::Plot_Standard_Layer( PLOTTER*    aPlotter,
 
             case PAD_OVAL:
                 if( aSkipNPTH_Pads &&
-                    (pad->m_Size.x == pad->m_Drill.x ) &&
-                    (pad->m_Size.y == pad->m_Drill.y ) &&
+                    (pad->m_Size.x() == pad->m_Drill.x() ) &&
+                    (pad->m_Size.y() == pad->m_Drill.y() ) &&
                     (pad->m_Attribut == PAD_HOLE_NOT_PLATED) )
                     break;
 
@@ -1018,7 +1018,7 @@ void PCB_BASE_FRAME::PlotDrillMark( PLOTTER*    aPlotter,
     {
         for( PtPad = Module->m_Pads; PtPad != NULL; PtPad = PtPad->Next() )
         {
-            if( PtPad->m_Drill.x == ZERO_LENGTH )
+            if( PtPad->m_Drill.x() == ZERO_LENGTH )
                 continue;
 
             // Output hole shapes:
@@ -1026,13 +1026,13 @@ void PCB_BASE_FRAME::PlotDrillMark( PLOTTER*    aPlotter,
 
             if( PtPad->m_DrillShape == PAD_OVAL )
             {
-                diam.x = TO_LEGACY_LU( PtPad->m_Drill.x );
-                diam.y = TO_LEGACY_LU( PtPad->m_Drill.y );
+                diam.x = TO_LEGACY_LU( PtPad->m_Drill.x() );
+                diam.y = TO_LEGACY_LU( PtPad->m_Drill.y() );
                 aPlotter->flash_pad_oval( pos, diam, PtPad->m_Orient, aTraceMode );
             }
             else
             {
-                diam.x = aSmallDrillShape ? SMALL_DRILL : TO_LEGACY_LU( PtPad->m_Drill.x );
+                diam.x = aSmallDrillShape ? SMALL_DRILL : TO_LEGACY_LU( PtPad->m_Drill.x() );
                 aPlotter->flash_pad_circle( pos, diam.x, aTraceMode );
             }
         }

pcbnew/print_board_functions.cpp

@@ -352,17 +352,17 @@ static void Print_Module( EDA_DRAW_PANEL* aPanel, wxDC* aDC, MODULE* aModule,
 
         // Manage hole according to the print drill option
         wxSize drill_tmp;
-        drill_tmp.x = TO_LEGACY_LU( pt_pad->m_Drill.x );
-        drill_tmp.y = TO_LEGACY_LU( pt_pad->m_Drill.y );
+        drill_tmp.x = TO_LEGACY_LU( pt_pad->m_Drill.x() );
+        drill_tmp.y = TO_LEGACY_LU( pt_pad->m_Drill.y() );
 
         switch ( aDrillShapeOpt )
         {
             case PRINT_PARAMETERS::NO_DRILL_SHAPE:
-                pt_pad->m_Drill = VECTOR_PCB(ZERO_LENGTH, ZERO_LENGTH); //wxSize(0,0);
+                pt_pad->m_Drill = VECTOR_PCB::fromXY(ZERO_LENGTH, ZERO_LENGTH); //wxSize(0,0);
                 break;
             case PRINT_PARAMETERS::SMALL_DRILL_SHAPE:
-                pt_pad->m_Drill.x = MIN(FROM_LEGACY_LU( SMALL_DRILL ),pt_pad->m_Drill.x );
-                pt_pad->m_Drill.y = MIN(FROM_LEGACY_LU( SMALL_DRILL ),pt_pad->m_Drill.y );
+                pt_pad->m_Drill.x() = min( FROM_LEGACY_LU( SMALL_DRILL ),pt_pad->m_Drill.x() );
+                pt_pad->m_Drill.y() = min( FROM_LEGACY_LU( SMALL_DRILL ),pt_pad->m_Drill.y() );
                 break;
             case PRINT_PARAMETERS::FULL_DRILL_SHAPE:
                 // Do nothing
@@ -370,8 +370,8 @@ static void Print_Module( EDA_DRAW_PANEL* aPanel, wxDC* aDC, MODULE* aModule,
         }
 
         pt_pad->Draw( aPanel, aDC, aDraw_mode );
-        pt_pad->m_Drill.x = FROM_LEGACY_LU( drill_tmp.x );
-        pt_pad->m_Drill.y = FROM_LEGACY_LU( drill_tmp.y );
+        pt_pad->m_Drill.x() = FROM_LEGACY_LU( drill_tmp.x );
+        pt_pad->m_Drill.y() = FROM_LEGACY_LU( drill_tmp.y );
     }
 
     /* Print footprint graphic shapes */

pcbnew/solve.cpp

@@ -464,8 +464,8 @@ static int Autoroute_One_Track( PCB_EDIT_FRAME* pcbframe,
                  + pcbframe->GetBoard()->m_BoundaryBox.m_Pos.x;
         int cY = ( Board.m_GridRouting * row_source )
                  + pcbframe->GetBoard()->m_BoundaryBox.m_Pos.y;
-        int dx = TO_LEGACY_LU( pt_cur_ch->m_PadStart->m_Size.x / 2 );
-        int dy = TO_LEGACY_LU( pt_cur_ch->m_PadStart->m_Size.y / 2 );
+        int dx = TO_LEGACY_LU( pt_cur_ch->m_PadStart->m_Size.x() / 2 );
+        int dy = TO_LEGACY_LU( pt_cur_ch->m_PadStart->m_Size.y() / 2 );
         int px = pt_cur_ch->m_PadStart->GetPosition().x;
         int py = pt_cur_ch->m_PadStart->GetPosition().y;
 
@@ -479,8 +479,8 @@ static int Autoroute_One_Track( PCB_EDIT_FRAME* pcbframe,
              + pcbframe->GetBoard()->m_BoundaryBox.m_Pos.x;
         cY = ( Board.m_GridRouting * row_target )
              + pcbframe->GetBoard()->m_BoundaryBox.m_Pos.y;
-        dx = TO_LEGACY_LU( pt_cur_ch->m_PadEnd->m_Size.x / 2 );
-        dy = TO_LEGACY_LU( pt_cur_ch->m_PadEnd->m_Size.y / 2 );
+        dx = TO_LEGACY_LU( pt_cur_ch->m_PadEnd->m_Size.x() / 2 );
+        dy = TO_LEGACY_LU( pt_cur_ch->m_PadEnd->m_Size.y() / 2 );
         px = pt_cur_ch->m_PadEnd->GetPosition().x;
         py = pt_cur_ch->m_PadEnd->GetPosition().y;
 

pcbnew/specctra_export.cpp

@@ -250,7 +250,7 @@ static bool isRoundKeepout( D_PAD* aPad )
 {
     if( aPad->m_PadShape==PAD_CIRCLE )
     {
-        if( aPad->m_Drill.x >= aPad->m_Size.x )
+        if( aPad->m_Drill.x() >= aPad->m_Size.x() )
             return true;
 
         if( (aPad->m_layerMask & ALL_CU_LAYERS) == 0 )
@@ -321,11 +321,11 @@ PADSTACK* SPECCTRA_DB::makePADSTACK( BOARD* aBoard, D_PAD* aPad )
 
     POINT   dsnOffset;
 
-    if( aPad->m_Offset.x != ZERO_LENGTH || aPad->m_Offset.y != ZERO_LENGTH )
+    if( aPad->m_Offset.x() != ZERO_LENGTH || aPad->m_Offset.y() != ZERO_LENGTH )
     {
         char offsetTxt[64]; /// @BUG !!!Unsafe
 
-        wxPoint offset( TO_LEGACY_LU( aPad->m_Offset.x ), TO_LEGACY_LU( aPad->m_Offset.y ) );
+        wxPoint offset( TO_LEGACY_LU( aPad->m_Offset.x() ), TO_LEGACY_LU( aPad->m_Offset.y() ) );
 
         dsnOffset = mapPt( offset );
 
@@ -341,7 +341,7 @@ PADSTACK* SPECCTRA_DB::makePADSTACK( BOARD* aBoard, D_PAD* aPad )
     default:
     case PAD_CIRCLE:
         {
-            double  diameter = scale( TO_LEGACY_LU( aPad->m_Size.x ) );
+            double  diameter = scale( TO_LEGACY_LU( aPad->m_Size.x() ) );
 
             for( int ndx=0;  ndx<reportedLayers;  ++ndx )
             {
@@ -357,7 +357,7 @@ PADSTACK* SPECCTRA_DB::makePADSTACK( BOARD* aBoard, D_PAD* aPad )
             }
 
             snprintf( name, sizeof(name), "Round%sPad_%.6g_mil",
-                     uniqifier.c_str(), scale(TO_LEGACY_LU( aPad->m_Size.x ) ) );
+                     uniqifier.c_str(), scale(TO_LEGACY_LU( aPad->m_Size.x() ) ) );
             name[ sizeof(name)-1 ] = 0;
 
             padstack->SetPadstackId( name );
@@ -366,8 +366,8 @@ PADSTACK* SPECCTRA_DB::makePADSTACK( BOARD* aBoard, D_PAD* aPad )
 
     case PAD_RECT:
         {
-            double dx = scale( TO_LEGACY_LU( aPad->m_Size.x ) ) / 2.0;
-            double dy = scale( TO_LEGACY_LU( aPad->m_Size.y ) ) / 2.0;
+            double dx = scale( TO_LEGACY_LU( aPad->m_Size.x() ) ) / 2.0;
+            double dy = scale( TO_LEGACY_LU( aPad->m_Size.y() ) ) / 2.0;
 
             POINT   lowerLeft( -dx, -dy );
             POINT   upperRight( dx, dy );
@@ -388,7 +388,7 @@ PADSTACK* SPECCTRA_DB::makePADSTACK( BOARD* aBoard, D_PAD* aPad )
             }
 
             snprintf( name, sizeof(name),  "Rect%sPad_%.6gx%.6g_mil",
-                     uniqifier.c_str(), scale( TO_LEGACY_LU( aPad->m_Size.x ) ), scale( TO_LEGACY_LU( aPad->m_Size.y ) )  );
+                     uniqifier.c_str(), scale( TO_LEGACY_LU( aPad->m_Size.x() ) ), scale( TO_LEGACY_LU( aPad->m_Size.y() ) )  );
             name[ sizeof(name)-1 ] = 0;
 
             padstack->SetPadstackId( name );
@@ -397,8 +397,8 @@ PADSTACK* SPECCTRA_DB::makePADSTACK( BOARD* aBoard, D_PAD* aPad )
 
     case PAD_OVAL:
         {
-            double  dx = scale( TO_LEGACY_LU( aPad->m_Size.x ) ) / 2.0;
-            double  dy = scale( TO_LEGACY_LU( aPad->m_Size.y ) ) / 2.0;
+            double  dx = scale( TO_LEGACY_LU( aPad->m_Size.x() ) ) / 2.0;
+            double  dy = scale( TO_LEGACY_LU( aPad->m_Size.y() ) ) / 2.0;
             double  dr = dx - dy;
             double  radius;
             POINT   start;
@@ -436,7 +436,7 @@ PADSTACK* SPECCTRA_DB::makePADSTACK( BOARD* aBoard, D_PAD* aPad )
             }
 
             snprintf( name, sizeof(name),  "Oval%sPad_%.6gx%.6g_mil",
-                     uniqifier.c_str(), scale( TO_LEGACY_LU( aPad->m_Size.x ) ), scale( TO_LEGACY_LU( aPad->m_Size.y ) )  );
+                     uniqifier.c_str(), scale( TO_LEGACY_LU( aPad->m_Size.x() ) ), scale( TO_LEGACY_LU( aPad->m_Size.y() ) )  );
             name[ sizeof(name)-1 ] = 0;
 
             padstack->SetPadstackId( name );
@@ -445,11 +445,11 @@ PADSTACK* SPECCTRA_DB::makePADSTACK( BOARD* aBoard, D_PAD* aPad )
 
     case PAD_TRAPEZOID:
         {
-            double dx = scale( TO_LEGACY_LU( aPad->m_Size.x ) ) / 2.0;
-            double dy = scale( TO_LEGACY_LU( aPad->m_Size.y ) ) / 2.0;
+            double dx = scale( TO_LEGACY_LU( aPad->m_Size.x() ) ) / 2.0;
+            double dy = scale( TO_LEGACY_LU( aPad->m_Size.y() ) ) / 2.0;
 
-            double ddx = scale( TO_LEGACY_LU( aPad->m_DeltaSize.x ) ) / 2.0;
-            double ddy = scale( TO_LEGACY_LU( aPad->m_DeltaSize.y ) ) / 2.0;
+            double ddx = scale( TO_LEGACY_LU( aPad->m_DeltaSize.x() ) ) / 2.0;
+            double ddy = scale( TO_LEGACY_LU( aPad->m_DeltaSize.y() ) ) / 2.0;
 
             // see class_pad_draw_functions.cpp which draws the trapezoid pad
             POINT   lowerLeft(  -dx - ddy, -dy - ddx );
@@ -483,11 +483,11 @@ PADSTACK* SPECCTRA_DB::makePADSTACK( BOARD* aBoard, D_PAD* aPad )
 
             // this string _must_ be unique for a given physical shape
             snprintf( name, sizeof(name), "Trapz%sPad_%.6gx%.6g_%c%.6gx%c%.6g_mil",
-                     uniqifier.c_str(), scale( TO_LEGACY_LU( aPad->m_Size.x ) ), scale( TO_LEGACY_LU( aPad->m_Size.y ) ),
-                     aPad->m_DeltaSize.x < ZERO_LENGTH ? 'n' : 'p',
-                     abs( scale( TO_LEGACY_LU( aPad->m_DeltaSize.x ) )),
-                     aPad->m_DeltaSize.y < ZERO_LENGTH ? 'n' : 'p',
-                     abs( scale( TO_LEGACY_LU( aPad->m_DeltaSize.y ) ))
+                     uniqifier.c_str(), scale( TO_LEGACY_LU( aPad->m_Size.x() ) ), scale( TO_LEGACY_LU( aPad->m_Size.y() ) ),
+                     aPad->m_DeltaSize.x() < ZERO_LENGTH ? 'n' : 'p',
+                     fabs( scale( TO_LEGACY_LU( aPad->m_DeltaSize.x() ) )),
+                     aPad->m_DeltaSize.y() < ZERO_LENGTH ? 'n' : 'p',
+                     fabs( scale( TO_LEGACY_LU( aPad->m_DeltaSize.y() ) ))
                      );
             name[ sizeof(name)-1 ] = 0;
 
@@ -527,7 +527,7 @@ IMAGE* SPECCTRA_DB::makeIMAGE( BOARD* aBoard, MODULE* aModule )
         // see if this pad is a through hole with no copper on its perimeter
         if( isRoundKeepout( pad ) )
         {
-            double  diameter = scale( TO_LEGACY_LU( pad->m_Drill.x ) );
+            double  diameter = scale( TO_LEGACY_LU( pad->m_Drill.x() ) );
             POINT   vertex   = mapPt( TO_LEGACY_LU_WXP( pad->m_Pos0 ) );
 
             int layerCount = aBoard->GetCopperLayerCount();

pcbnew/zones_convert_brd_items_to_polygons_with_Boost.cpp

@@ -201,7 +201,7 @@ void ZONE_CONTAINER::AddClearanceAreasPolygonsToPolysList( BOARD* aPcb )
                  * inside the board (in fact inside the hole. Some photo diodes and Leds are
                  * like this)
                  */
-                if( (pad->m_Drill.x == ZERO_LENGTH) && (pad->m_Drill.y == ZERO_LENGTH) )
+                if( (pad->m_Drill.x() == ZERO_LENGTH) && (pad->m_Drill.y() == ZERO_LENGTH) )
                     continue;
 
                 // Use a dummy pad to calculate a hole shape that have the same dimension as

pcbnew/zones_convert_to_polygons_aux_functions.cpp

@@ -68,15 +68,15 @@ void BuildUnconnectedThermalStubsPolygonList( std::vector<CPolyPt>& aCornerBuffe
             // Thermal bridges are like a segment from a starting point inside the pad
             // to an ending point outside the pad
             wxPoint startpoint, endpoint;
-            endpoint.x = ( TO_LEGACY_LU( pad->m_Size.x / 2 ) ) + aZone->m_ThermalReliefGapValue;
-            endpoint.y = ( TO_LEGACY_LU( pad->m_Size.y / 2 ) ) + aZone->m_ThermalReliefGapValue;
+            endpoint.x = ( TO_LEGACY_LU( pad->m_Size.x() / 2 ) ) + aZone->m_ThermalReliefGapValue;
+            endpoint.y = ( TO_LEGACY_LU( pad->m_Size.y() / 2 ) ) + aZone->m_ThermalReliefGapValue;
 
             int copperThickness = aZone->m_ThermalReliefCopperBridgeValue - aZone->m_ZoneMinThickness;
             if( copperThickness < 0 )
                 copperThickness = 0;
 
-            startpoint.x = min( TO_LEGACY_LU( pad->m_Size.x ), copperThickness );
-            startpoint.y = min( TO_LEGACY_LU( pad->m_Size.y ), copperThickness );
+            startpoint.x = min( TO_LEGACY_LU( pad->m_Size.x() ), copperThickness );
+            startpoint.y = min( TO_LEGACY_LU( pad->m_Size.y() ), copperThickness );
             startpoint.x /= 2;
             startpoint.y /= 2;
 

polygon/math_for_graphics.h

@@ -1,8 +1,8 @@
 // math stuff for graphics, from FreePCB
 
-#ifndef abs
+/*#ifndef abs
 #define abs(x) (((x) >=0) ? (x) : (-(x)))
-#endif
+#endif*/
 
 
 typedef struct PointTag

potrace/auxiliary.h

@@ -73,6 +73,8 @@ static inline int floordiv( int a, int n )
 
 
 /* Note: the following work for integers and other numeric types. */
+/* those are bad programming practice because of several issues with
+overloading and integer limits
 #undef sign
 #undef abs
 #undef min
@@ -84,6 +86,79 @@ static inline int floordiv( int a, int n )
 #define min( a, b ) ( (a)<(b) ? (a) : (b) )
 #define max( a, b ) ( (a)>(b) ? (a) : (b) )
 #define sq( a )     ( (a) * (a) )
-#define cu( a )     ( (a) * (a) * (a) )
+#define cu( a )     ( (a) * (a) * (a) )*/
+
+// these functions better than macros because they do not cause double evaluation.
+static inline int sign( int x )
+{
+    return (0 < x) - (x < 0);
+}
+
+static inline int sign( long x )
+{
+    return (0 < x) - (x < 0);
+}
+
+static inline int sign( double x )
+{
+    return (0.0 < x) - (x < 0.0);
+}
+
+/*static inline int abs( int x ) is not required because exist in stdlib.h */
+
+static inline long abs( long x )
+{
+    return x < 0? -x : x;
+}
+
+static inline int max( int x, int y )
+{
+    return x < y? y : x;
+}
+
+static inline long max( long x, long y )
+{
+    return x < y? y : x;
+}
+
+static inline int min( int x, int y )
+{
+    return x < y? x : y;
+}
+
+static inline long min( long x, long y )
+{
+    return x < y? x : y;
+}
+
+static inline int sq( int x )
+{
+    return x * x;
+}
+
+static inline long sq( long x )
+{
+    return x * x;
+}
+
+static inline double sq( double x )
+{
+    return x * x;
+}
+
+static inline int cu( int x )
+{
+    return x * x * x;
+}
+
+static inline long cu( long x )
+{
+    return x * x * x;
+}
+
+static inline double cu( double x )
+{
+    return x * x * x;
+}
 
 #endif /* AUXILIARY_H */

potrace/render.cpp

@@ -278,7 +278,7 @@ void render_curveto( render_t* rm,
      *  occur at an endpoint. */
     dd0     = sq( x1 - 2 * x2 + x3 ) + sq( y1 - 2 * y2 + y3 );
     dd1     = sq( x2 - 2 * x3 + x4 ) + sq( y2 - 2 * y3 + y4 );
-    dd      = 6 * sqrt( max( dd0, dd1 ) );
+    dd      = 6 * sqrt( fmax( dd0, dd1 ) );
     e2      = 8 * delta <= dd ? 8 * delta / dd : 1;
     epsilon = sqrt( e2 ); /* necessary interval size */