/** * @file trigo.cpp * @brief Trigonometric functions. */ #include "fctsys.h" #include "macros.h" #include "trigo.h" bool TestSegmentHit( wxPoint aRefPoint, wxPoint aStart, wxPoint aEnd, int aDist ) { // make coordinates relatives to aStart: aEnd -= aStart; aRefPoint -= aStart; return DistanceTest( aDist, aEnd.x, aEnd.y, aRefPoint.x, aRefPoint.y ); } bool DistanceTest( int seuil, int dx, int dy, int spot_cX, int spot_cY ) { /* We can have 4 cases:: * horizontal segment * vertical segment * 45 degrees segment * other slopes */ int cXrot, cYrot, segX, segY; int pointX, pointY; segX = dx; segY = dy; pointX = spot_cX; pointY = spot_cY; /* Recalculating coord for the segment is in 1st quadrant (coord >= 0) */ if( segX < 0 ) /* set > 0 by symmetry about the Y axis */ { segX = -segX; pointX = -pointX; } if( segY < 0 ) /* set > 0 by symmetry about the X axis */ { segY = -segY; pointY = -pointY; } if( segY == 0 ) /* horizontal */ { if( abs( pointY ) <= seuil ) { if( ( pointX >= 0 ) && ( pointX <= segX ) ) return 1; if( ( pointX < 0 ) && ( pointX >= -seuil ) ) { if( ( ( pointX * pointX ) + ( pointY * pointY ) ) <= ( seuil * seuil ) ) return true; } if( ( pointX > segX ) && ( pointX <= ( segX + seuil ) ) ) { if( ( ( ( pointX - segX ) * ( pointX - segX ) ) + ( pointY * pointY ) ) <= ( seuil * seuil ) ) return true; } } } else if( segX == 0 ) /* vertical */ { if( abs( pointX ) <= seuil ) { if( ( pointY >= 0 ) && ( pointY <= segY ) ) return true; if( ( pointY < 0 ) && ( pointY >= -seuil ) ) { if( ( ( pointY * pointY ) + ( pointX * pointX ) ) <= ( seuil * seuil ) ) return true; } if( ( pointY > segY ) && ( pointY <= ( segY + seuil ) ) ) { if( ( ( ( pointY - segY ) * ( pointY - segY ) ) + ( pointX * pointX ) ) <= ( seuil * seuil ) ) return true; } } } else if( segX == segY ) /* 45 degrees */ { /* Rotate axes of 45 degrees. mouse was then * Coord: x1 = x * y * cos45 + sin45 * y1 = y * cos45 - sin45 x * * And the segment of track is horizontal. * Coord recalculation of the mouse (sin45 = cos45 = .707 = 7 / 10 * Note: sin or cos45 = .707, and when recalculating coord * dx45 and dy45, lect coeff .707 is neglected, dx and dy are * actually 0707 times * Too big. (security hole too small) * Spot_cX, Y * must be by .707 * .707 = 0.5 */ cXrot = (pointX + pointY) >> 1; cYrot = (pointY - pointX) >> 1; /* Recalculating coord of segment extremity, which will be vertical * following the orientation of axes on the screen: dx45 = pointx * (or pointy) and 1.414 is actually greater, and dy45 = 0 */ // * Threshold should be .707 to reflect the change in coeff dx, dy seuil *= 7; seuil /= 10; if( abs( cYrot ) <= seuil ) /* ok on vertical axis */ { if( ( cXrot >= 0 ) && ( cXrot <= segX ) ) return true; /* Check extremes using the radius of a circle. */ if( ( cXrot < 0 ) && ( cXrot >= -seuil ) ) { if( ( ( cXrot * cXrot ) + ( cYrot * cYrot ) ) <= ( seuil * seuil ) ) return true; } if( ( cXrot > segX ) && ( cXrot <= ( segX + seuil ) ) ) { if( ( ( ( cXrot - segX ) * ( cXrot - segX ) ) + ( cYrot * cYrot ) ) <= ( seuil * seuil ) ) return true; } } } else /* any orientation */ { /* There is a change of axis (rotation), so that the segment * track is horizontal in the new reference */ int angle; angle = wxRound( ( atan2( (double) segY, (double) segX ) * 1800.0 / M_PI ) ); cXrot = pointX; cYrot = pointY; RotatePoint( &cXrot, &cYrot, angle ); /* Rotate the point to be tested */ RotatePoint( &segX, &segY, angle ); /* Rotate the segment */ /* The track is horizontal, following the amendments to coordinate * axis and, therefore segX = length of segment */ if( abs( cYrot ) <= seuil ) /* vertical axis */ { if( ( cXrot >= 0 ) && ( cXrot <= segX ) ) return true; if( ( cXrot < 0 ) && ( cXrot >= -seuil ) ) { if( ( ( cXrot * cXrot ) + ( cYrot * cYrot ) ) <= ( seuil * seuil ) ) return true; } if( ( cXrot > segX ) && ( cXrot <= ( segX + seuil ) ) ) { if( ( ( ( cXrot - segX ) * ( cXrot - segX ) ) + ( cYrot * cYrot ) ) <= ( seuil * seuil ) ) return true; } } } return false; } int ArcTangente( int dy, int dx ) { double fangle; if( dy == 0 ) { if( dx >= 0 ) return 0; else return -1800; } if( dx == 0 ) { if( dy >= 0 ) return 900; else return -900; } if( dx == dy ) { if( dx >= 0 ) return 450; else return -1800 + 450; } if( dx == -dy ) { if( dx >= 0 ) return -450; else return 1800 - 450; } fangle = atan2( (double) dy, (double) dx ) / M_PI * 1800; return wxRound( fangle ); } void RotatePoint( int* pX, int* pY, int angle ) { int tmp; while( angle < 0 ) angle += 3600; while( angle >= 3600 ) angle -= 3600; // Cheap and dirty optimizations for 0, 90, 180, and 270 degrees. if( angle == 0 ) return; if( angle == 900 ) /* sin = 1, cos = 0 */ { tmp = *pX; *pX = *pY; *pY = -tmp; } else if( angle == 1800 ) /* sin = 0, cos = -1 */ { *pX = -*pX; *pY = -*pY; } else if( angle == 2700 ) /* sin = -1, cos = 0 */ { tmp = *pX; *pX = -*pY; *pY = tmp; } else { double fangle = DEG2RAD( (double) angle / 10.0 ); double fpx = (*pY * sin( fangle ) ) + (*pX * cos( fangle ) ); double fpy = (*pY * cos( fangle ) ) - (*pX * sin( fangle ) ); *pX = wxRound( fpx ); *pY = wxRound( fpy ); } } void RotatePoint( int* pX, int* pY, int cx, int cy, int angle ) { int ox, oy; ox = *pX - cx; oy = *pY - cy; RotatePoint( &ox, &oy, angle ); *pX = ox + cx; *pY = oy + cy; } void RotatePoint( wxPoint* point, int angle ) { int ox, oy; ox = point->x; oy = point->y; RotatePoint( &ox, &oy, angle ); point->x = ox; point->y = oy; } void RotatePoint( wxPoint* point, const wxPoint& centre, int angle ) { int ox, oy; ox = point->x - centre.x; oy = point->y - centre.y; RotatePoint( &ox, &oy, angle ); point->x = ox + centre.x; point->y = oy + centre.y; } void RotatePoint( double* pX, double* pY, double cx, double cy, int angle ) { double ox, oy; ox = *pX - cx; oy = *pY - cy; RotatePoint( &ox, &oy, angle ); *pX = ox + cx; *pY = oy + cy; } void RotatePoint( double* pX, double* pY, int angle ) { double tmp; while( angle < 0 ) angle += 3600; while( angle >= 3600 ) angle -= 3600; // Cheap and dirty optimizations for 0, 90, 180, and 270 degrees. if( angle == 0 ) return; if( angle == 900 ) /* sin = 1, cos = 0 */ { tmp = *pX; *pX = *pY; *pY = -tmp; } else if( angle == 1800 ) /* sin = 0, cos = -1 */ { *pX = -*pX; *pY = -*pY; } else if( angle == 2700 ) /* sin = -1, cos = 0 */ { tmp = *pX; *pX = -*pY; *pY = tmp; } else { double fangle = DEG2RAD( (double) angle / 10.0 ); double fpx = (*pY * sin( fangle ) ) + (*pX * cos( fangle ) ); double fpy = (*pY * cos( fangle ) ) - (*pX * sin( fangle ) ); *pX = fpx; *pY = fpy; } } double EuclideanNorm( wxPoint vector ) { return sqrt( (double) vector.x * (double) vector.x + (double) vector.y * (double) vector.y ); } wxPoint TwoPointVector( wxPoint startPoint, wxPoint endPoint ) { return endPoint - startPoint; } double DistanceLinePoint( wxPoint linePointA, wxPoint linePointB, wxPoint referencePoint ) { return fabs( (double) ( (linePointB.x - linePointA.x) * (linePointA.y - referencePoint.y) - (linePointA.x - referencePoint.x ) * (linePointB.y - linePointA.y) ) / EuclideanNorm( TwoPointVector( linePointA, linePointB ) ) ); } bool HitTestPoints( wxPoint pointA, wxPoint pointB, double threshold ) { wxPoint vectorAB = TwoPointVector( pointA, pointB ); double distance = EuclideanNorm( vectorAB ); return distance < threshold; } int CrossProduct( wxPoint vectorA, wxPoint vectorB ) { return vectorA.x * vectorB.y - vectorA.y * vectorB.x; } double GetLineLength( const wxPoint& aPointA, const wxPoint& aPointB ) { return sqrt( pow( (double) aPointA.x - (double) aPointB.x, 2 ) + pow( (double) aPointA.y - (double) aPointB.y, 2 ) ); }