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5b70cdbdc12c19eee9ddb20f2a0ef60be1fb098d
rdkit/Code/ForceField/MMFF/StretchBend.cpp
ptosco 5b70cdbdc1 - added relative DistanceConstraints (i.e., +/- with respect 
to the current value) (C++/Python)
- added absolute/relative AngleConstraints (C++/Python)
- added absolute/relative TorsionConstraints (C++/Python)
- added PositionConstraints (C++/Python)
- exposed fixedPoints from Python
- added relevant C++/Python tests
- removed a number of redundant "this->" in member functions
- moved some getGrad() code into Utils::calcAngleBendGrad and
  Utils::calcTorsionGrad to avoid repeating the same code
  for constraints
2013-12-02 19:58:29 +01:00

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// $Id$
//
// Copyright (C) 2013 Paolo Tosco
//
// Copyright (C) 2004-2006 Rational Discovery LLC
//
// @@ All Rights Reserved @@
// This file is part of the RDKit.
// The contents are covered by the terms of the BSD license
// which is included in the file license.txt, found at the root
// of the RDKit source tree.
//
#include "StretchBend.h"
#include "AngleBend.h"
#include "BondStretch.h"
#include "Params.h"
#include <cmath>
#include <ForceField/ForceField.h>
#include <RDGeneral/Invariant.h>
#include <RDGeneral/utils.h>
namespace ForceFields {
namespace MMFF {
namespace Utils {
std::pair<double, double> calcStbnForceConstants
(const std::pair<bool, const MMFFStbn *> mmffStbnParams)
{
PRECONDITION(mmffStbnParams.second, "stretch-bend parameters not found");
return (mmffStbnParams.first
? std::make_pair((mmffStbnParams.second)->kbaKJI, (mmffStbnParams.second)->kbaIJK)
: std::make_pair((mmffStbnParams.second)->kbaIJK, (mmffStbnParams.second)->kbaKJI));
}
std::pair<double, double> calcStretchBendEnergy
(const double deltaDist1, const double deltaDist2,
const double deltaTheta, const std::pair<double, double> forceConstants)
{
double factor = 2.51210 * deltaTheta;
return std::make_pair(factor * forceConstants.first * deltaDist1,
factor * forceConstants.second * deltaDist2);
}
} // end of namespace Utils
StretchBendContrib::StretchBendContrib(ForceField *owner,
const unsigned int idx1, const unsigned int idx2, const unsigned int idx3,
const std::pair<bool, const MMFFStbn *> mmffStbnParams,
const MMFFAngle *mmffAngleParams, const MMFFBond *mmffBondParams1,
const MMFFBond *mmffBondParams2)
{
PRECONDITION(owner, "bad owner");
PRECONDITION(((idx1 != idx2) && (idx2 != idx3) && (idx1 != idx3)), "degenerate points");
RANGE_CHECK(0, idx1, owner->positions().size() - 1);
RANGE_CHECK(0, idx2, owner->positions().size() - 1);
RANGE_CHECK(0, idx3, owner->positions().size() - 1);
dp_forceField = owner;
d_at1Idx = idx1;
d_at2Idx = idx2;
d_at3Idx = idx3;
d_restLen1 = Utils::calcBondRestLength(mmffBondParams1);
d_restLen2 = Utils::calcBondRestLength(mmffBondParams2);
d_theta0 = Utils::calcAngleRestValue(mmffAngleParams);
d_forceConstants = Utils::calcStbnForceConstants(mmffStbnParams);
}
double StretchBendContrib::getEnergy(double *pos) const
{
PRECONDITION(dp_forceField,"no owner");
PRECONDITION(pos,"bad vector");
double dist1 = dp_forceField->distance(d_at1Idx, d_at2Idx,pos);
double dist2 = dp_forceField->distance(d_at2Idx, d_at3Idx,pos);
RDGeom::Point3D p1(pos[3 * d_at1Idx],
pos[3 * d_at1Idx + 1],
pos[3 * d_at1Idx + 2]);
RDGeom::Point3D p2(pos[3 * d_at2Idx],
pos[3 * d_at2Idx + 1],
pos[3 * d_at2Idx + 2]);
RDGeom::Point3D p3(pos[3 * d_at3Idx],
pos[3 * d_at3Idx + 1],
pos[3 * d_at3Idx + 2]);
std::pair<double, double> stretchBendEnergies =
Utils::calcStretchBendEnergy(dist1 - d_restLen1,
dist2 - d_restLen2, RAD2DEG * acos(Utils::calcCosTheta
(p1, p2, p3, dist1, dist2)) - d_theta0, d_forceConstants);
return (stretchBendEnergies.first + stretchBendEnergies.second);
}
void StretchBendContrib::getGrad(double *pos, double *grad) const
{
PRECONDITION(dp_forceField, "no owner");
PRECONDITION(pos, "bad vector");
PRECONDITION(grad, "bad vector");
double dist1 = dp_forceField->distance(d_at1Idx, d_at2Idx, pos);
double dist2 = dp_forceField->distance(d_at2Idx, d_at3Idx, pos);
RDGeom::Point3D p1(pos[3 * d_at1Idx],
pos[3 * d_at1Idx + 1], pos[3 * d_at1Idx + 2]);
RDGeom::Point3D p2(pos[3 * d_at2Idx],
pos[3 * d_at2Idx + 1], pos[3 * d_at2Idx + 2]);
RDGeom::Point3D p3(pos[3 * d_at3Idx],
pos[3 * d_at3Idx + 1], pos[3 * d_at3Idx + 2]);
double *g1 = &(grad[3 * d_at1Idx]);
double *g2 = &(grad[3 * d_at2Idx]);
double *g3 = &(grad[3 * d_at3Idx]);
RDGeom::Point3D p12 = (p1 - p2) / dist1;
RDGeom::Point3D p32 = (p3 - p2) / dist2;
double cosTheta = p12.dotProduct(p32);
double sinThetaSq = 1.0 - cosTheta * cosTheta;
double sinTheta = std::max(((sinThetaSq > 0.0) ? sqrt(sinThetaSq) : 0.0), 1.0e-8);
double angleTerm = RAD2DEG * acos(cosTheta) - d_theta0;
double distTerm = RAD2DEG * (d_forceConstants.first * (dist1 - d_restLen1)
+ d_forceConstants.second * (dist2 - d_restLen2));
double dCos_dS1 = 1.0 / dist1 * (p32.x - cosTheta * p12.x);
double dCos_dS2 = 1.0 / dist1 * (p32.y - cosTheta * p12.y);
double dCos_dS3 = 1.0 / dist1 * (p32.z - cosTheta * p12.z);
double dCos_dS4 = 1.0 / dist2 * (p12.x - cosTheta * p32.x);
double dCos_dS5 = 1.0 / dist2 * (p12.y - cosTheta * p32.y);
double dCos_dS6 = 1.0 / dist2 * (p12.z - cosTheta * p32.z);
g1[0] += 2.51210 * (p12.x * d_forceConstants.first
* angleTerm + dCos_dS1 / (-sinTheta) * distTerm);
g1[1] += 2.51210 * (p12.y * d_forceConstants.first
* angleTerm + dCos_dS2 / (-sinTheta) * distTerm);
g1[2] += 2.51210 * (p12.z * d_forceConstants.first
* angleTerm + dCos_dS3 / (-sinTheta) * distTerm);
g2[0] += 2.51210 * ((-p12.x * d_forceConstants.first
- p32.x * d_forceConstants.second) * angleTerm
+ (-dCos_dS1 - dCos_dS4) / (-sinTheta) * distTerm);
g2[1] += 2.51210 * ((-p12.y * d_forceConstants.first
- p32.y * d_forceConstants.second) * angleTerm
+ (-dCos_dS2 - dCos_dS5) / (-sinTheta) * distTerm);
g2[2] += 2.51210 * ((-p12.z * d_forceConstants.first
- p32.z * d_forceConstants.second) * angleTerm
+ (-dCos_dS3 - dCos_dS6) / (-sinTheta) * distTerm);
g3[0] += 2.51210 * (p32.x * d_forceConstants.second
* angleTerm + dCos_dS4 / (-sinTheta) * distTerm);
g3[1] += 2.51210 * (p32.y * d_forceConstants.second
* angleTerm + dCos_dS5 / (-sinTheta) * distTerm);
g3[2] += 2.51210 * (p32.z * d_forceConstants.second
* angleTerm + dCos_dS6 / (-sinTheta) * distTerm);
}
}
}
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