ResInsight/ApplicationLibCode/Application/Tools/WellPathTools/RiaPolyArcLineSampler.cpp

/////////////////////////////////////////////////////////////////////////////////
//
//  Copyright (C) 2018-     Equinor ASA
//
//  ResInsight is free software: you can redistribute it and/or modify
//  it under the terms of the GNU General Public License as published by
//  the Free Software Foundation, either version 3 of the License, or
//  (at your option) any later version.
//
//  ResInsight is distributed in the hope that it will be useful, but WITHOUT ANY
//  WARRANTY; without even the implied warranty of MERCHANTABILITY or
//  FITNESS FOR A PARTICULAR PURPOSE.
//
//  See the GNU General Public License at <http://www.gnu.org/licenses/gpl.html>
//  for more details.
//
/////////////////////////////////////////////////////////////////////////////////

#include "RiaPolyArcLineSampler.h"
#include "RiaArcCurveCalculator.h"

#include "cvfGeometryTools.h"
#include "cvfMatrix4.h"

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
RiaPolyArcLineSampler::RiaPolyArcLineSampler( const cvf::Vec3d&              startTangent,
                                              const std::vector<cvf::Vec3d>& lineArcEndPoints )
    : m_startTangent( startTangent )
    , m_lineArcEndPoints( lineArcEndPoints )
    , m_maxSamplingsInterval( 0.15 )
    , m_isResamplingLines( true )
    , m_totalMD( 0.0 )
{
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
std::pair<std::vector<cvf::Vec3d>, std::vector<double>>
    RiaPolyArcLineSampler::sampledPointsAndMDs( double sampleInterval, bool isResamplingLines )
{
    CVF_ASSERT( sampleInterval > 0.0 );

    m_maxSamplingsInterval = sampleInterval;
    m_isResamplingLines    = isResamplingLines;

    m_points.clear();
    m_meshDs.clear();

    double startMD = 0.0;

    std::vector<cvf::Vec3d> pointsNoDuplicates = RiaPolyArcLineSampler::pointsWithoutDuplicates( m_lineArcEndPoints );

    if ( pointsNoDuplicates.size() < 2 ) return std::make_pair( m_points, m_meshDs );

    m_totalMD = startMD;

    cvf::Vec3d p1 = pointsNoDuplicates[0];

    m_points.push_back( p1 );
    m_meshDs.push_back( m_totalMD );

    cvf::Vec3d t2 = m_startTangent;

    for ( size_t pIdx = 0; pIdx < pointsNoDuplicates.size() - 1; ++pIdx )
    {
        sampleSegment( t2, pointsNoDuplicates[pIdx], pointsNoDuplicates[pIdx + 1], &t2 );
    }

    return std::make_pair( m_points, m_meshDs );
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RiaPolyArcLineSampler::sampleSegment( cvf::Vec3d t1, cvf::Vec3d p1, cvf::Vec3d p2, cvf::Vec3d* endTangent )
{
    cvf::Vec3d p1p2 = p2 - p1;

    CVF_ASSERT( p1p2.lengthSquared() > 1e-20 );

    if ( cvf::GeometryTools::getAngle( t1, p1p2 ) < 1e-5 || p1p2.length() < m_maxSamplingsInterval )
    {
        sampleLine( p1, p2, endTangent );
    }
    else // resample arc
    {
        sampleArc( t1, p1, p2, endTangent );
    }
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
std::vector<cvf::Vec3d> RiaPolyArcLineSampler::pointsWithoutDuplicates( const std::vector<cvf::Vec3d>& points )
{
    std::vector<cvf::Vec3d> outputPoints;

    cvf::Vec3d   previousPoint = cvf::Vec3d::UNDEFINED;
    const double threshold     = 1e-6;
    for ( const auto& p : points )
    {
        if ( previousPoint.isUndefined() || ( ( previousPoint - p ).lengthSquared() ) > threshold )
        {
            outputPoints.push_back( p );
            previousPoint = p;
        }
    }

    return outputPoints;
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RiaPolyArcLineSampler::sampleLine( cvf::Vec3d p1, cvf::Vec3d p2, cvf::Vec3d* endTangent )
{
    cvf::Vec3d p1p2 = p2 - p1;

    double p1p2Length = p1p2.length();

    if ( m_isResamplingLines && p1p2Length > m_maxSamplingsInterval )
    {
        cvf::Vec3d tp1p2 = p1p2 / p1p2Length;
        double     mdInc = m_maxSamplingsInterval;
        while ( mdInc < p1p2Length )
        {
            cvf::Vec3d ps = p1 + mdInc * tp1p2;
            m_points.push_back( ps );
            m_meshDs.push_back( m_totalMD + mdInc );
            mdInc += m_maxSamplingsInterval;
        }
    }

    m_totalMD += p1p2Length;
    m_points.push_back( p2 );
    m_meshDs.push_back( m_totalMD );

    ( *endTangent ) = p1p2.getNormalized();
}

//--------------------------------------------------------------------------------------------------
///
//--------------------------------------------------------------------------------------------------
void RiaPolyArcLineSampler::sampleArc( cvf::Vec3d t1, cvf::Vec3d p1, cvf::Vec3d p2, cvf::Vec3d* endTangent )
{
    // Find arc CS
    RiaArcCurveCalculator CS_rad( p1, t1, p2 );

    double     radius = CS_rad.radius();
    cvf::Mat4d arcCS  = CS_rad.arcCS();

    double angleInc = m_maxSamplingsInterval / radius;

    angleInc = angleInc < m_maxSamplingArcAngle ? angleInc : m_maxSamplingArcAngle; // Angle from 6 deg dogleg on 10 m

    cvf::Vec3d C = CS_rad.center();
    cvf::Vec3d N = CS_rad.normal();

    // Sample arc by
    // Rotate vector an increment, and transform to arc CS

    double arcAngle = cvf::GeometryTools::getAngle( N, p1 - C, p2 - C );
    if ( arcAngle / angleInc > 5000 )
    {
        angleInc = arcAngle / 5000;
    }

    for ( double angle = angleInc; angle < arcAngle; angle += angleInc )
    {
        cvf::Vec3d C_to_incP = cvf::Vec3d::X_AXIS;
        C_to_incP *= radius;
        C_to_incP.transformVector( cvf::Mat3d::fromRotation( cvf::Vec3d::Z_AXIS, angle ) );

        C_to_incP.transformPoint( arcCS );

        m_points.push_back( C_to_incP );
        m_meshDs.push_back( m_totalMD + angle * radius );
    }

    m_totalMD += arcAngle * radius;
    m_points.push_back( p2 );
    m_meshDs.push_back( m_totalMD );

    ( *endTangent ) = CS_rad.endTangent();
}