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Commit cecc774a authored by Peter Eastman's avatar Peter Eastman
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Merge branch 'master' into hardwall

parents 1dfa0e59 a20944f6
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Showing with 257 additions and 4068 deletions
platforms/reference/include/ReferenceAngleBondIxn.h
View file @ cecc774a
......@@ -29,7 +29,7 @@
namespace OpenMM {
class ReferenceAngleBondIxn : public ReferenceBondIxn {
class OPENMM_EXPORT ReferenceAngleBondIxn : public ReferenceBondIxn {
private:
......
platforms/reference/include/ReferenceKernels.h
View file @ cecc774a
......@@ -37,6 +37,7 @@
#include "SimTKOpenMMRealType.h"
#include "ReferenceNeighborList.h"
#include "lepton/CompiledExpression.h"
#include "lepton/CustomFunction.h"
#include "lepton/ExpressionProgram.h"
namespace OpenMM {
......@@ -795,11 +796,23 @@ public:
*/
void copyParametersToContext(ContextImpl& context, const CustomExternalForce& force);
private:
class PeriodicDistanceFunction;
int numParticles;
std::vector<int> particles;
RealOpenMM **particleParamArray;
Lepton::CompiledExpression energyExpression, forceExpressionX, forceExpressionY, forceExpressionZ;
std::vector<std::string> parameterNames, globalParameterNames;
RealVec* boxVectors;
};
class ReferenceCalcCustomExternalForceKernel::PeriodicDistanceFunction : public Lepton::CustomFunction {
public:
RealVec** boxVectorHandle;
PeriodicDistanceFunction(RealVec** boxVectorHandle);
int getNumArguments() const;
double evaluate(const double* arguments) const;
double evaluateDerivative(const double* arguments, const int* derivOrder) const;
Lepton::CustomFunction* clone() const;
};
/**
......
platforms/reference/include/ReferenceStochasticDynamics.h
View file @ cecc774a
......@@ -111,13 +111,26 @@ class OPENMM_EXPORT ReferenceStochasticDynamics : public ReferenceDynamics {
@param atomCoordinates atom coordinates
@param velocities velocities
@param forces forces
@param masses atom masses
@param inverseMasses inverse atom masses
--------------------------------------------------------------------------------------- */
virtual void updatePart2(int numberOfAtoms, std::vector<OpenMM::RealVec>& atomCoordinates, std::vector<OpenMM::RealVec>& velocities,
std::vector<OpenMM::RealVec>& forces, std::vector<RealOpenMM>& inverseMasses, std::vector<OpenMM::RealVec>& xPrime);
/**---------------------------------------------------------------------------------------
Third update
@param numberOfAtoms number of atoms
@param atomCoordinates atom coordinates
@param velocities velocities
@param inverseMasses inverse atom masses
--------------------------------------------------------------------------------------- */
virtual void updatePart3(int numberOfAtoms, std::vector<OpenMM::RealVec>& atomCoordinates, std::vector<OpenMM::RealVec>& velocities,
std::vector<RealOpenMM>& inverseMasses, std::vector<OpenMM::RealVec>& xPrime);
};
} // namespace OpenMM
......
platforms/reference/src/ReferenceKernels.cpp
View file @ cecc774a
......@@ -77,6 +77,7 @@
#include "openmm/OpenMMException.h"
#include "SimTKOpenMMUtilities.h"
#include "lepton/CustomFunction.h"
#include "lepton/Operation.h"
#include "lepton/Parser.h"
#include "lepton/ParsedExpression.h"
#include <cmath>
......@@ -146,6 +147,17 @@ static ReferenceConstraints& extractConstraints(ContextImpl& context) {
return *(ReferenceConstraints*) data->constraints;
}
/**
* Make sure an expression doesn't use any undefined variables.
*/
static void validateVariables(const Lepton::ExpressionTreeNode& node, const set<string>& variables) {
const Lepton::Operation& op = node.getOperation();
if (op.getId() == Lepton::Operation::VARIABLE && variables.find(op.getName()) == variables.end())
throw OpenMMException("Unknown variable in expression: "+op.getName());
for (int i = 0; i < (int) node.getChildren().size(); i++)
validateVariables(node.getChildren()[i], variables);
}
/**
* Compute the kinetic energy of the system, possibly shifting the velocities in time to account
* for a leapfrog integrator.
......@@ -422,6 +434,11 @@ void ReferenceCalcCustomBondForceKernel::initialize(const System& system, const
parameterNames.push_back(force.getPerBondParameterName(i));
for (int i = 0; i < force.getNumGlobalParameters(); i++)
globalParameterNames.push_back(force.getGlobalParameterName(i));
set<string> variables;
variables.insert("r");
variables.insert(parameterNames.begin(), parameterNames.end());
variables.insert(globalParameterNames.begin(), globalParameterNames.end());
validateVariables(expression.getRootNode(), variables);
}
double ReferenceCalcCustomBondForceKernel::execute(ContextImpl& context, bool includeForces, bool includeEnergy) {
......@@ -536,6 +553,11 @@ void ReferenceCalcCustomAngleForceKernel::initialize(const System& system, const
parameterNames.push_back(force.getPerAngleParameterName(i));
for (int i = 0; i < force.getNumGlobalParameters(); i++)
globalParameterNames.push_back(force.getGlobalParameterName(i));
set<string> variables;
variables.insert("theta");
variables.insert(parameterNames.begin(), parameterNames.end());
variables.insert(globalParameterNames.begin(), globalParameterNames.end());
validateVariables(expression.getRootNode(), variables);
}
double ReferenceCalcCustomAngleForceKernel::execute(ContextImpl& context, bool includeForces, bool includeEnergy) {
......@@ -780,6 +802,11 @@ void ReferenceCalcCustomTorsionForceKernel::initialize(const System& system, con
parameterNames.push_back(force.getPerTorsionParameterName(i));
for (int i = 0; i < force.getNumGlobalParameters(); i++)
globalParameterNames.push_back(force.getGlobalParameterName(i));
set<string> variables;
variables.insert("theta");
variables.insert(parameterNames.begin(), parameterNames.end());
variables.insert(globalParameterNames.begin(), globalParameterNames.end());
validateVariables(expression.getRootNode(), variables);
}
double ReferenceCalcCustomTorsionForceKernel::execute(ContextImpl& context, bool includeForces, bool includeEnergy) {
......@@ -1038,6 +1065,14 @@ void ReferenceCalcCustomNonbondedForceKernel::initialize(const System& system, c
globalParameterNames.push_back(force.getGlobalParameterName(i));
globalParamValues[force.getGlobalParameterName(i)] = force.getGlobalParameterDefaultValue(i);
}
set<string> variables;
variables.insert("r");
for (int i = 0; i < numParameters; i++) {
variables.insert(parameterNames[i]+"1");
variables.insert(parameterNames[i]+"2");
}
variables.insert(globalParameterNames.begin(), globalParameterNames.end());
validateVariables(expression.getRootNode(), variables);
// Delete the custom functions.
......@@ -1314,6 +1349,18 @@ void ReferenceCalcCustomGBForceKernel::initialize(const System& system, const Cu
valueDerivExpressions.resize(force.getNumComputedValues());
valueGradientExpressions.resize(force.getNumComputedValues());
set<string> particleVariables, pairVariables;
pairVariables.insert("r");
particleVariables.insert("x");
particleVariables.insert("y");
particleVariables.insert("z");
for (int i = 0; i < numPerParticleParameters; i++) {
particleVariables.insert(particleParameterNames[i]);
pairVariables.insert(particleParameterNames[i]+"1");
pairVariables.insert(particleParameterNames[i]+"2");
}
particleVariables.insert(globalParameterNames.begin(), globalParameterNames.end());
pairVariables.insert(globalParameterNames.begin(), globalParameterNames.end());
for (int i = 0; i < force.getNumComputedValues(); i++) {
string name, expression;
CustomGBForce::ComputationType type;
......@@ -1322,15 +1369,21 @@ void ReferenceCalcCustomGBForceKernel::initialize(const System& system, const Cu
valueExpressions.push_back(ex.createProgram());
valueTypes.push_back(type);
valueNames.push_back(name);
if (i == 0)
if (i == 0) {
valueDerivExpressions[i].push_back(ex.differentiate("r").optimize().createProgram());
validateVariables(ex.getRootNode(), pairVariables);
}
else {
valueGradientExpressions[i].push_back(ex.differentiate("x").optimize().createProgram());
valueGradientExpressions[i].push_back(ex.differentiate("y").optimize().createProgram());
valueGradientExpressions[i].push_back(ex.differentiate("z").optimize().createProgram());
for (int j = 0; j < i; j++)
valueDerivExpressions[i].push_back(ex.differentiate(valueNames[j]).optimize().createProgram());
validateVariables(ex.getRootNode(), particleVariables);
}
particleVariables.insert(name);
pairVariables.insert(name+"1");
pairVariables.insert(name+"2");
}
// Parse the expressions for energy terms.
......@@ -1352,10 +1405,12 @@ void ReferenceCalcCustomGBForceKernel::initialize(const System& system, const Cu
energyGradientExpressions[i].push_back(ex.differentiate("x").optimize().createProgram());
energyGradientExpressions[i].push_back(ex.differentiate("y").optimize().createProgram());
energyGradientExpressions[i].push_back(ex.differentiate("z").optimize().createProgram());
validateVariables(ex.getRootNode(), particleVariables);
}
else {
energyDerivExpressions[i].push_back(ex.differentiate(valueNames[j]+"1").optimize().createProgram());
energyDerivExpressions[i].push_back(ex.differentiate(valueNames[j]+"2").optimize().createProgram());
validateVariables(ex.getRootNode(), pairVariables);
}
}
}
......@@ -1402,6 +1457,46 @@ void ReferenceCalcCustomGBForceKernel::copyParametersToContext(ContextImpl& cont
}
}
ReferenceCalcCustomExternalForceKernel::PeriodicDistanceFunction::PeriodicDistanceFunction(RealVec** boxVectorHandle) : boxVectorHandle(boxVectorHandle) {
}
int ReferenceCalcCustomExternalForceKernel::PeriodicDistanceFunction::getNumArguments() const {
return 6;
}
double ReferenceCalcCustomExternalForceKernel::PeriodicDistanceFunction::evaluate(const double* arguments) const {
RealVec* boxVectors = *boxVectorHandle;
RealVec delta = RealVec(arguments[0], arguments[1], arguments[2])-RealVec(arguments[3], arguments[4], arguments[5]);
delta -= boxVectors[2]*floor(delta[2]/boxVectors[2][2]+0.5);
delta -= boxVectors[1]*floor(delta[1]/boxVectors[1][1]+0.5);
delta -= boxVectors[0]*floor(delta[0]/boxVectors[0][0]+0.5);
return sqrt(delta.dot(delta));
}
double ReferenceCalcCustomExternalForceKernel::PeriodicDistanceFunction::evaluateDerivative(const double* arguments, const int* derivOrder) const {
int argIndex = -1;
for (int i = 0; i < 6; i++) {
if (derivOrder[i] > 0) {
if (derivOrder[i] > 1 || argIndex != -1)
throw OpenMMException("Unsupported derivative of periodicdistance"); // Should be impossible for this to happen.
argIndex = i;
}
}
RealVec* boxVectors = *boxVectorHandle;
RealVec delta = RealVec(arguments[0], arguments[1], arguments[2])-RealVec(arguments[3], arguments[4], arguments[5]);
delta -= boxVectors[2]*floor(delta[2]/boxVectors[2][2]+0.5);
delta -= boxVectors[1]*floor(delta[1]/boxVectors[1][1]+0.5);
delta -= boxVectors[0]*floor(delta[0]/boxVectors[0][0]+0.5);
double r = sqrt(delta.dot(delta));
if (argIndex < 3)
return delta[argIndex]/r;
return -delta[argIndex-3]/r;
}
Lepton::CustomFunction* ReferenceCalcCustomExternalForceKernel::PeriodicDistanceFunction::clone() const {
return new PeriodicDistanceFunction(boxVectorHandle);
}
ReferenceCalcCustomExternalForceKernel::~ReferenceCalcCustomExternalForceKernel() {
disposeRealArray(particleParamArray, numParticles);
}
......@@ -1423,7 +1518,10 @@ void ReferenceCalcCustomExternalForceKernel::initialize(const System& system, co
// Parse the expression used to calculate the force.
Lepton::ParsedExpression expression = Lepton::Parser::parse(force.getEnergyFunction()).optimize();
map<string, Lepton::CustomFunction*> functions;
PeriodicDistanceFunction periodicDistance(&boxVectors);
functions["periodicdistance"] = &periodicDistance;
Lepton::ParsedExpression expression = Lepton::Parser::parse(force.getEnergyFunction(), functions).optimize();
energyExpression = expression.createCompiledExpression();
forceExpressionX = expression.differentiate("x").createCompiledExpression();
forceExpressionY = expression.differentiate("y").createCompiledExpression();
......@@ -1432,11 +1530,19 @@ void ReferenceCalcCustomExternalForceKernel::initialize(const System& system, co
parameterNames.push_back(force.getPerParticleParameterName(i));
for (int i = 0; i < force.getNumGlobalParameters(); i++)
globalParameterNames.push_back(force.getGlobalParameterName(i));
set<string> variables;
variables.insert("x");
variables.insert("y");
variables.insert("z");
variables.insert(parameterNames.begin(), parameterNames.end());
variables.insert(globalParameterNames.begin(), globalParameterNames.end());
validateVariables(expression.getRootNode(), variables);
}
double ReferenceCalcCustomExternalForceKernel::execute(ContextImpl& context, bool includeForces, bool includeEnergy) {
vector<RealVec>& posData = extractPositions(context);
vector<RealVec>& forceData = extractForces(context);
boxVectors = extractBoxVectors(context);
RealOpenMM energy = 0;
map<string, double> globalParameters;
for (int i = 0; i < (int) globalParameterNames.size(); i++)
......
platforms/reference/src/SimTKReference/ReferenceStochasticDynamics.cpp
View file @ cecc774a
......@@ -163,8 +163,18 @@ void ReferenceStochasticDynamics::updatePart2(int numberOfAtoms, vector<RealVec>
for (int ii = 0; ii < numberOfAtoms; ii++) {
if (inverseMasses[ii] != 0.0)
for (int jj = 0; jj < 3; jj++)
xPrime[ii][jj] = atomCoordinates[ii][jj]+getDeltaT()*velocities[ii][jj];
xPrime[ii] = atomCoordinates[ii]+velocities[ii]*getDeltaT();
}
}
void ReferenceStochasticDynamics::updatePart3(int numberOfAtoms, vector<RealVec>& atomCoordinates,
vector<RealVec>& velocities, vector<RealOpenMM>& inverseMasses,
vector<RealVec>& xPrime) {
RealOpenMM invStepSize = 1.0/getDeltaT();
for (int i = 0; i < numberOfAtoms; ++i)
if (inverseMasses[i] != 0) {
velocities[i] = (xPrime[i]-atomCoordinates[i])*invStepSize;
atomCoordinates[i] = xPrime[i];
}
}
......@@ -221,13 +231,7 @@ void ReferenceStochasticDynamics::update(const OpenMM::System& system, vector<Re
// copy xPrime -> atomCoordinates
RealOpenMM invStepSize = 1.0/getDeltaT();
for (int i = 0; i < numberOfAtoms; ++i)
if (masses[i] != zero)
for (int j = 0; j < 3; ++j) {
velocities[i][j] = invStepSize*(xPrime[i][j]-atomCoordinates[i][j]);
atomCoordinates[i][j] = xPrime[i][j];
}
updatePart3(numberOfAtoms, atomCoordinates, velocities, inverseMasses, xPrime);
ReferenceVirtualSites::computePositions(system, atomCoordinates);
incrementTimeStep();
......
platforms/reference/tests/ReferenceTests.h 0 → 100644
View file @ cecc774a
/* -------------------------------------------------------------------------- *
* OpenMM *
* -------------------------------------------------------------------------- *
* This is part of the OpenMM molecular simulation toolkit originating from *
* Simbios, the NIH National Center for Physics-Based Simulation of *
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
* Permission is hereby granted, free of charge, to any person obtaining a *
* copy of this software and associated documentation files (the "Software"), *
* to deal in the Software without restriction, including without limitation *
* the rights to use, copy, modify, merge, publish, distribute, sublicense, *
* and/or sell copies of the Software, and to permit persons to whom the *
* Software is furnished to do so, subject to the following conditions: *
* *
* The above copyright notice and this permission notice shall be included in *
* all copies or substantial portions of the Software. *
* *
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR *
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, *
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL *
* THE AUTHORS, CONTRIBUTORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, *
* DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR *
* OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE *
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
#ifdef WIN32
#define _USE_MATH_DEFINES // Needed to get M_PI
#endif
#include "ReferencePlatform.h"
OpenMM::ReferencePlatform platform;
void initializeTests(int argc, char* argv[]) {
}
platforms/reference/tests/TestReferenceAndersenThermostat.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2008-2009 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,190 +29,8 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of AndersenThermostat.
*/
#include "ReferenceTests.h"
#include "TestAndersenThermostat.h"
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/AndersenThermostat.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/NonbondedForce.h"
#include "openmm/System.h"
#include "openmm/VerletIntegrator.h"
#include "SimTKOpenMMRealType.h"
#include "sfmt/SFMT.h"
#include <iostream>
#include <vector>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
void testTemperature() {
const int numParticles = 8;
const double temp = 100.0;
const double collisionFreq = 10.0;
const int numSteps = 5000;
System system;
VerletIntegrator integrator(0.003);
NonbondedForce* forceField = new NonbondedForce();
for (int i = 0; i < numParticles; ++i) {
system.addParticle(2.0);
forceField->addParticle((i%2 == 0 ? 1.0 : -1.0), 1.0, 5.0);
}
system.addForce(forceField);
AndersenThermostat* thermostat = new AndersenThermostat(temp, collisionFreq);
system.addForce(thermostat);
ASSERT(!thermostat->usesPeriodicBoundaryConditions());
Context context(system, integrator, platform);
vector<Vec3> positions(numParticles);
for (int i = 0; i < numParticles; ++i)
positions[i] = Vec3((i%2 == 0 ? 2 : -2), (i%4 < 2 ? 2 : -2), (i < 4 ? 2 : -2));
context.setPositions(positions);
context.setVelocitiesToTemperature(temp);
// Let it equilibrate.
integrator.step(10000);
// Now run it for a while and see if the temperature is correct.
double ke = 0.0;
for (int i = 0; i < numSteps; ++i) {
State state = context.getState(State::Energy);
ke += state.getKineticEnergy();
integrator.step(10);
}
ke /= numSteps;
double expected = 0.5*numParticles*3*BOLTZ*temp;
ASSERT_USUALLY_EQUAL_TOL(expected, ke, 0.1);
}
void testConstraints() {
const int numParticles = 8;
const double temp = 100.0;
const double collisionFreq = 10.0;
const int numSteps = 15000;
System system;
VerletIntegrator integrator(0.004);
NonbondedForce* forceField = new NonbondedForce();
for (int i = 0; i < numParticles; ++i) {
system.addParticle(2.0);
forceField->addParticle((i%2 == 0 ? 1.0 : -1.0), 1.0, 5.0);
}
system.addForce(forceField);
system.addConstraint(0, 1, 1);
system.addConstraint(1, 2, 1);
system.addConstraint(2, 3, 1);
system.addConstraint(3, 0, 1);
system.addConstraint(4, 5, 1);
system.addConstraint(5, 6, 1);
system.addConstraint(6, 7, 1);
system.addConstraint(7, 4, 1);
AndersenThermostat* thermostat = new AndersenThermostat(temp, collisionFreq);
system.addForce(thermostat);
Context context(system, integrator, platform);
vector<Vec3> positions(numParticles);
positions[0] = Vec3(0, 0, 0);
positions[1] = Vec3(1, 0, 0);
positions[2] = Vec3(1, 1, 0);
positions[3] = Vec3(0, 1, 0);
positions[4] = Vec3(1, 0, 1);
positions[5] = Vec3(1, 1, 1);
positions[6] = Vec3(0, 1, 1);
positions[7] = Vec3(0, 0, 1);
context.setPositions(positions);
context.setVelocitiesToTemperature(temp);
// Let it equilibrate.
integrator.step(5000);
// Now run it for a while and see if the temperature is correct.
double ke = 0.0;
for (int i = 0; i < numSteps; ++i) {
State state = context.getState(State::Energy);
ke += state.getKineticEnergy();
integrator.step(1);
}
ke /= numSteps;
double expected = 0.5*(numParticles*3-system.getNumConstraints())*BOLTZ*temp;
ASSERT_USUALLY_EQUAL_TOL(expected, ke, 0.1);
}
void testRandomSeed() {
const int numParticles = 8;
const double temp = 100.0;
const double collisionFreq = 10.0;
System system;
VerletIntegrator integrator(0.01);
NonbondedForce* forceField = new NonbondedForce();
for (int i = 0; i < numParticles; ++i) {
system.addParticle(2.0);
forceField->addParticle((i%2 == 0 ? 1.0 : -1.0), 1.0, 5.0);
}
system.addForce(forceField);
AndersenThermostat* thermostat = new AndersenThermostat(temp, collisionFreq);
system.addForce(thermostat);
vector<Vec3> positions(numParticles);
vector<Vec3> velocities(numParticles);
for (int i = 0; i < numParticles; ++i) {
positions[i] = Vec3((i%2 == 0 ? 2 : -2), (i%4 < 2 ? 2 : -2), (i < 4 ? 2 : -2));
velocities[i] = Vec3(0, 0, 0);
}
// Try twice with the same random seed.
thermostat->setRandomNumberSeed(5);
Context context(system, integrator, platform);
context.setPositions(positions);
context.setVelocities(velocities);
integrator.step(10);
State state1 = context.getState(State::Positions);
context.reinitialize();
context.setPositions(positions);
context.setVelocities(velocities);
integrator.step(10);
State state2 = context.getState(State::Positions);
// Try twice with a different random seed.
thermostat->setRandomNumberSeed(10);
context.reinitialize();
context.setPositions(positions);
context.setVelocities(velocities);
integrator.step(10);
State state3 = context.getState(State::Positions);
context.reinitialize();
context.setPositions(positions);
context.setVelocities(velocities);
integrator.step(10);
State state4 = context.getState(State::Positions);
// Compare the results.
for (int i = 0; i < numParticles; i++) {
for (int j = 0; j < 3; j++) {
ASSERT(state1.getPositions()[i][j] == state2.getPositions()[i][j]);
ASSERT(state3.getPositions()[i][j] == state4.getPositions()[i][j]);
ASSERT(state1.getPositions()[i][j] != state3.getPositions()[i][j]);
}
}
}
int main() {
try {
testTemperature();
testConstraints();
testRandomSeed();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
void runPlatformTests() {
}
platforms/reference/tests/TestReferenceBrownianIntegrator.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2008 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,241 +29,8 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of BrownianIntegrator.
*/
#include "ReferenceTests.h"
#include "TestBrownianIntegrator.h"
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/HarmonicBondForce.h"
#include "openmm/NonbondedForce.h"
#include "openmm/System.h"
#include "openmm/BrownianIntegrator.h"
#include "SimTKOpenMMRealType.h"
#include "sfmt/SFMT.h"
#include <iostream>
#include <vector>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
void testSingleBond() {
System system;
system.addParticle(2.0);
system.addParticle(2.0);
double dt = 0.01;
BrownianIntegrator integrator(0, 0.1, dt);
HarmonicBondForce* forceField = new HarmonicBondForce();
forceField->addBond(0, 1, 1.5, 1);
system.addForce(forceField);
Context context(system, integrator, platform);
vector<Vec3> positions(2);
positions[0] = Vec3(-1, 0, 0);
positions[1] = Vec3(1, 0, 0);
context.setPositions(positions);
// This is simply an overdamped harmonic oscillator, so compare it to the analytical solution.
double rate = 2*1.0/(0.1*2.0);
for (int i = 0; i < 1000; ++i) {
State state = context.getState(State::Positions | State::Velocities);
double time = state.getTime();
double expectedDist = 1.5+0.5*std::exp(-rate*time);
ASSERT_EQUAL_VEC(Vec3(-0.5*expectedDist, 0, 0), state.getPositions()[0], 0.02);
ASSERT_EQUAL_VEC(Vec3(0.5*expectedDist, 0, 0), state.getPositions()[1], 0.02);
if (i > 0) {
double expectedSpeed = -0.5*rate*std::exp(-rate*(time-0.5*dt));
ASSERT_EQUAL_VEC(Vec3(-0.5*expectedSpeed, 0, 0), state.getVelocities()[0], 0.11);
ASSERT_EQUAL_VEC(Vec3(0.5*expectedSpeed, 0, 0), state.getVelocities()[1], 0.11);
}
integrator.step(1);
}
}
void testTemperature() {
const int numParticles = 8;
const int numBonds = numParticles-1;
const double temp = 10.0;
System system;
BrownianIntegrator integrator(temp, 2.0, 0.01);
HarmonicBondForce* forceField = new HarmonicBondForce();
for (int i = 0; i < numParticles; ++i) {
system.addParticle(2.0);
}
for (int i = 0; i < numBonds; ++i)
forceField->addBond(i, i+1, 1.0, 5.0);
system.addForce(forceField);
Context context(system, integrator, platform);
vector<Vec3> positions(numParticles);
for (int i = 0; i < numParticles; ++i)
positions[i] = Vec3(i, 0, 0);
context.setPositions(positions);
// Let it equilibrate.
integrator.step(10000);
// Now run it for a while and see if the temperature is correct.
double pe = 0.0;
const int steps = 50000;
for (int i = 0; i < steps; ++i) {
State state = context.getState(State::Energy);
pe += state.getPotentialEnergy();
integrator.step(1);
}
pe /= steps;
double expected = 0.5*numBonds*BOLTZ*temp;
ASSERT_USUALLY_EQUAL_TOL(expected, pe, 0.1*expected);
}
void testConstraints() {
const int numParticles = 8;
const double temp = 100.0;
System system;
BrownianIntegrator integrator(temp, 2.0, 0.001);
integrator.setConstraintTolerance(1e-5);
NonbondedForce* forceField = new NonbondedForce();
for (int i = 0; i < numParticles; ++i) {
system.addParticle(10.0);
forceField->addParticle((i%2 == 0 ? 0.2 : -0.2), 0.5, 5.0);
}
for (int i = 0; i < numParticles-1; ++i)
system.addConstraint(i, i+1, 1.0);
system.addForce(forceField);
Context context(system, integrator, platform);
vector<Vec3> positions(numParticles);
vector<Vec3> velocities(numParticles);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
for (int i = 0; i < numParticles; ++i) {
positions[i] = Vec3(i/2, (i+1)/2, 0);
velocities[i] = Vec3(genrand_real2(sfmt)-0.5, genrand_real2(sfmt)-0.5, genrand_real2(sfmt)-0.5);
}
context.setPositions(positions);
context.setVelocities(velocities);
// Simulate it and see whether the constraints remain satisfied.
for (int i = 0; i < 1000; ++i) {
State state = context.getState(State::Positions);
for (int j = 0; j < numParticles-1; ++j) {
Vec3 p1 = state.getPositions()[j];
Vec3 p2 = state.getPositions()[j+1];
double dist = std::sqrt((p1[0]-p2[0])*(p1[0]-p2[0])+(p1[1]-p2[1])*(p1[1]-p2[1])+(p1[2]-p2[2])*(p1[2]-p2[2]));
ASSERT_EQUAL_TOL(1.0, dist, 2e-5);
}
integrator.step(1);
}
}
void testConstrainedMasslessParticles() {
System system;
system.addParticle(0.0);
system.addParticle(1.0);
system.addConstraint(0, 1, 1.5);
vector<Vec3> positions(2);
positions[0] = Vec3(-1, 0, 0);
positions[1] = Vec3(1, 0, 0);
BrownianIntegrator integrator(300.0, 2.0, 0.01);
bool failed = false;
try {
// This should throw an exception.
Context context(system, integrator, platform);
}
catch (exception& ex) {
failed = true;
}
ASSERT(failed);
// Now make both particles massless, which should work.
system.setParticleMass(1, 0.0);
Context context(system, integrator, platform);
context.setPositions(positions);
context.setVelocitiesToTemperature(300.0);
integrator.step(1);
State state = context.getState(State::Velocities | State::Positions);
ASSERT_EQUAL(0.0, state.getVelocities()[0][0]);
}
void testRandomSeed() {
const int numParticles = 8;
const double temp = 100.0;
const double collisionFreq = 10.0;
System system;
BrownianIntegrator integrator(temp, 2.0, 0.001);
NonbondedForce* forceField = new NonbondedForce();
for (int i = 0; i < numParticles; ++i) {
system.addParticle(2.0);
forceField->addParticle((i%2 == 0 ? 1.0 : -1.0), 1.0, 5.0);
}
system.addForce(forceField);
vector<Vec3> positions(numParticles);
vector<Vec3> velocities(numParticles);
for (int i = 0; i < numParticles; ++i) {
positions[i] = Vec3((i%2 == 0 ? 2 : -2), (i%4 < 2 ? 2 : -2), (i < 4 ? 2 : -2));
velocities[i] = Vec3(0, 0, 0);
}
// Try twice with the same random seed.
integrator.setRandomNumberSeed(5);
Context context(system, integrator, platform);
context.setPositions(positions);
context.setVelocities(velocities);
integrator.step(10);
State state1 = context.getState(State::Positions);
context.reinitialize();
context.setPositions(positions);
context.setVelocities(velocities);
integrator.step(10);
State state2 = context.getState(State::Positions);
// Try twice with a different random seed.
integrator.setRandomNumberSeed(10);
context.reinitialize();
context.setPositions(positions);
context.setVelocities(velocities);
integrator.step(10);
State state3 = context.getState(State::Positions);
context.reinitialize();
context.setPositions(positions);
context.setVelocities(velocities);
integrator.step(10);
State state4 = context.getState(State::Positions);
// Compare the results.
for (int i = 0; i < numParticles; i++) {
for (int j = 0; j < 3; j++) {
ASSERT(state1.getPositions()[i][j] == state2.getPositions()[i][j]);
ASSERT(state3.getPositions()[i][j] == state4.getPositions()[i][j]);
ASSERT(state1.getPositions()[i][j] != state3.getPositions()[i][j]);
}
}
}
int main() {
try {
testSingleBond();
testTemperature();
testConstraints();
testConstrainedMasslessParticles();
testRandomSeed();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
void runPlatformTests() {
}
platforms/reference/tests/TestReferenceCMAPTorsionForce.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2010-2015 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,152 +29,8 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of CMAPTorsionForce.
*/
#include "ReferenceTests.h"
#include "TestCMAPTorsionForce.h"
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/CMAPTorsionForce.h"
#include "openmm/PeriodicTorsionForce.h"
#include "openmm/System.h"
#include "openmm/VerletIntegrator.h"
#include "SimTKOpenMMRealType.h"
#include "sfmt/SFMT.h"
#include <iostream>
#include <vector>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
void testCMAPTorsions() {
const int mapSize = 36;
// Create two systems: one with a pair of periodic torsions, and one with a CMAP torsion
// that approximates the same force.
System system1;
for (int i = 0; i < 5; i++)
system1.addParticle(1.0);
PeriodicTorsionForce* periodic = new PeriodicTorsionForce();
periodic->addTorsion(0, 1, 2, 3, 2, M_PI/4, 1.5);
periodic->addTorsion(1, 2, 3, 4, 3, M_PI/3, 2.0);
system1.addForce(periodic);
ASSERT(!periodic->usesPeriodicBoundaryConditions());
ASSERT(!system1.usesPeriodicBoundaryConditions());
System system2;
for (int i = 0; i < 5; i++)
system2.addParticle(1.0);
CMAPTorsionForce* cmap = new CMAPTorsionForce();
vector<double> mapEnergy(mapSize*mapSize);
for (int i = 0; i < mapSize; i++) {
double angle1 = i*2*M_PI/mapSize;
double energy1 = 1.5*(1+cos(2*angle1-M_PI/4));
for (int j = 0; j < mapSize; j++) {
double angle2 = j*2*M_PI/mapSize;
double energy2 = 2.0*(1+cos(3*angle2-M_PI/3));
mapEnergy[i+j*mapSize] = energy1+energy2;
}
}
cmap->addMap(mapSize, mapEnergy);
cmap->addTorsion(0, 0, 1, 2, 3, 1, 2, 3, 4);
system2.addForce(cmap);
ASSERT(!cmap->usesPeriodicBoundaryConditions());
ASSERT(!system2.usesPeriodicBoundaryConditions());
// Set the atoms in various positions, and verify that both systems give equal forces and energy.
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
vector<Vec3> positions(5);
VerletIntegrator integrator1(0.01);
VerletIntegrator integrator2(0.01);
Context c1(system1, integrator1, platform);
Context c2(system2, integrator2, platform);
for (int i = 0; i < 50; i++) {
for (int j = 0; j < (int) positions.size(); j++)
positions[j] = Vec3(5.0*genrand_real2(sfmt), 5.0*genrand_real2(sfmt), 5.0*genrand_real2(sfmt));
c1.setPositions(positions);
c2.setPositions(positions);
State s1 = c1.getState(State::Forces | State::Energy);
State s2 = c2.getState(State::Forces | State::Energy);
for (int i = 0; i < system1.getNumParticles(); i++)
ASSERT_EQUAL_VEC(s1.getForces()[i], s2.getForces()[i], 0.05);
ASSERT_EQUAL_TOL(s1.getPotentialEnergy(), s2.getPotentialEnergy(), 1e-3);
}
}
void testChangingParameters() {
// Create a system with two maps and one torsion.
const int mapSize = 8;
System system;
for (int i = 0; i < 5; i++)
system.addParticle(1.0);
CMAPTorsionForce* cmap = new CMAPTorsionForce();
vector<double> mapEnergy1(mapSize*mapSize);
vector<double> mapEnergy2(mapSize*mapSize);
for (int i = 0; i < mapSize; i++) {
double angle1 = i*2*M_PI/mapSize;
double energy1 = cos(angle1);
for (int j = 0; j < mapSize; j++) {
double angle2 = j*2*M_PI/mapSize;
double energy2 = 10*sin(angle2);
mapEnergy1[i+j*mapSize] = energy1+energy2;
mapEnergy2[i+j*mapSize] = energy1-energy2;
}
}
cmap->addMap(mapSize, mapEnergy1);
cmap->addMap(mapSize, mapEnergy2);
cmap->addTorsion(0, 0, 1, 2, 3, 1, 2, 3, 4);
system.addForce(cmap);
// Set particle positions so angle1=0 and angle2=PI/4.
vector<Vec3> positions(5);
positions[0] = Vec3(0, 0, 1);
positions[1] = Vec3(0, 0, 0);
positions[2] = Vec3(1, 0, 0);
positions[3] = Vec3(1, 0, 1);
positions[4] = Vec3(0.5, -0.5, 1);
VerletIntegrator integrator(0.01);
Context context(system, integrator, platform);
context.setPositions(positions);
// Check that the energy is correct.
double energy = context.getState(State::Energy).getPotentialEnergy();
ASSERT_EQUAL_TOL(1+10*sin(M_PI/4), energy, 1e-5);
// Modify the parameters.
cmap->setTorsionParameters(0, 1, 0, 1, 2, 3, 1, 2, 3, 4);
for (int i = 0; i < mapSize*mapSize; i++)
mapEnergy2[i] *= 2.0;
cmap->setMapParameters(1, mapSize, mapEnergy2);
cmap->updateParametersInContext(context);
// See if the results are correct.
energy = context.getState(State::Energy).getPotentialEnergy();
ASSERT_EQUAL_TOL(2-20*sin(M_PI/4), energy, 1e-5);
void runPlatformTests() {
}
int main() {
try {
testCMAPTorsions();
testChangingParameters();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
}
platforms/reference/tests/TestReferenceCMMotionRemover.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2008 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,89 +29,8 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of AndersenThermostat.
*/
#include "ReferenceTests.h"
#include "TestCMMotionRemover.h"
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/CMMotionRemover.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/HarmonicBondForce.h"
#include "openmm/NonbondedForce.h"
#include "openmm/System.h"
#include "openmm/VerletIntegrator.h"
#include "SimTKOpenMMRealType.h"
#include "sfmt/SFMT.h"
#include <iostream>
#include <vector>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
Vec3 calcCM(const vector<Vec3>& values, System& system) {
Vec3 cm;
for (int j = 0; j < system.getNumParticles(); ++j) {
cm[0] += values[j][0]*system.getParticleMass(j);
cm[1] += values[j][1]*system.getParticleMass(j);
cm[2] += values[j][2]*system.getParticleMass(j);
}
return cm;
}
void testMotionRemoval() {
const int numParticles = 8;
const double temp = 100.0;
const double collisionFreq = 10.0;
System system;
VerletIntegrator integrator(0.01);
HarmonicBondForce* bonds = new HarmonicBondForce();
bonds->addBond(2, 3, 2.0, 0.5);
system.addForce(bonds);
NonbondedForce* nonbonded = new NonbondedForce();
for (int i = 0; i < numParticles; ++i) {
system.addParticle(i+1);
nonbonded->addParticle((i%2 == 0 ? 1.0 : -1.0), 1.0, 5.0);
}
system.addForce(nonbonded);
CMMotionRemover* remover = new CMMotionRemover();
system.addForce(remover);
Context context(system, integrator, platform);
vector<Vec3> positions(numParticles);
vector<Vec3> velocities(numParticles);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
for (int i = 0; i < numParticles; ++i) {
positions[i] = Vec3((i%2 == 0 ? 2 : -2), (i%4 < 2 ? 2 : -2), (i < 4 ? 2 : -2));
velocities[i] = Vec3(genrand_real2(sfmt)-0.5, genrand_real2(sfmt)-0.5, genrand_real2(sfmt)-0.5);
}
context.setPositions(positions);
context.setVelocities(velocities);
// Now run it for a while and see if the center of mass remains fixed.
Vec3 cmPos = calcCM(context.getState(State::Positions).getPositions(), system);
for (int i = 0; i < 1000; ++i) {
integrator.step(1);
State state = context.getState(State::Positions | State::Velocities);
Vec3 pos = calcCM(state.getPositions(), system);
ASSERT_EQUAL_VEC(cmPos, pos, 1e-2);
Vec3 vel = calcCM(state.getVelocities(), system);
ASSERT_EQUAL_VEC(Vec3(0, 0, 0), vel, 1e-2);
}
}
int main() {
try {
testMotionRemoval();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
void runPlatformTests() {
}
platforms/reference/tests/TestReferenceCheckpoints.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2012-2013 Stanford University and the Authors. *
* Portions copyright (c) 2012-2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,49 +29,12 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests creating and loading checkpoints with the reference platform.
*/
#include "ReferencePlatform.h"
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/AndersenThermostat.h"
#include "openmm/Context.h"
#include "openmm/NonbondedForce.h"
#include "openmm/System.h"
#include "openmm/VerletIntegrator.h"
#include "sfmt/SFMT.h"
#include <iostream>
#include <sstream>
#include <vector>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
void compareStates(State& s1, State& s2) {
ASSERT_EQUAL_TOL(s1.getTime(), s2.getTime(), TOL);
int numParticles = s1.getPositions().size();
for (int i = 0; i < numParticles; i++) {
ASSERT_EQUAL_VEC(s1.getPositions()[i], s2.getPositions()[i], TOL);
ASSERT_EQUAL_VEC(s1.getVelocities()[i], s2.getVelocities()[i], TOL);
Vec3 a1, b1, c1, a2, b2, c2;
s1.getPeriodicBoxVectors(a1, b1, c1);
s2.getPeriodicBoxVectors(a2, b2, c2);
ASSERT_EQUAL_VEC(a1, a2, TOL);
ASSERT_EQUAL_VEC(b1, b2, TOL);
ASSERT_EQUAL_VEC(c1, c2, TOL);
for (map<string, double>::const_iterator iter = s1.getParameters().begin(); iter != s1.getParameters().end(); ++iter)
ASSERT_EQUAL(iter->second, (*s2.getParameters().find(iter->first)).second);
}
}
#include "ReferenceTests.h"
#include "TestCheckpoints.h"
void testCheckpoint() {
const int numParticles = 10;
const double boxSize = 3.0;
const int numParticles = 100;
const double boxSize = 5.0;
const double temperature = 200.0;
System system;
system.addForce(new AndersenThermostat(0.0, 100.0));
......@@ -84,7 +47,16 @@ void testCheckpoint() {
for (int i = 0; i < numParticles; i++) {
system.addParticle(1.0);
nonbonded->addParticle(i%2 == 0 ? 0.1 : -0.1, 0.2, 0.1);
bool clash;
do {
clash = false;
positions[i] = Vec3(boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt));
for (int j = 0; j < i; j++) {
Vec3 delta = positions[i]-positions[j];
if (sqrt(delta.dot(delta)) < 0.1)
clash = true;
}
} while (clash);
}
VerletIntegrator integrator(0.001);
Context context(system, integrator, platform);
......@@ -122,69 +94,6 @@ void testCheckpoint() {
compareStates(s2, s4);
}
void testSetState() {
const int numParticles = 10;
const double boxSize = 3.0;
const double temperature = 200.0;
System system;
system.addForce(new AndersenThermostat(0.0, 100.0));
NonbondedForce* nonbonded = new NonbondedForce();
system.addForce(nonbonded);
nonbonded->setNonbondedMethod(NonbondedForce::CutoffPeriodic);
vector<Vec3> positions(numParticles);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
for (int i = 0; i < numParticles; i++) {
system.addParticle(1.0);
nonbonded->addParticle(i%2 == 0 ? 0.1 : -0.1, 0.2, 0.1);
positions[i] = Vec3(boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt));
}
VerletIntegrator integrator(0.001);
Context context(system, integrator, platform);
context.setPositions(positions);
context.setPeriodicBoxVectors(Vec3(boxSize, 0, 0), Vec3(0, boxSize, 0), Vec3(0, 0, boxSize));
context.setParameter(AndersenThermostat::Temperature(), temperature);
// Run for a little while.
integrator.step(100);
// Record the current state.
State s1 = context.getState(State::Positions | State::Velocities | State::Parameters);
// Continue the simulation for a few more steps and record a partial state.
integrator.step(10);
State s2 = context.getState(State::Positions);
// Restore the original state and see if everything gets restored correctly.
context.setPeriodicBoxVectors(Vec3(2*boxSize, 0, 0), Vec3(0, 2*boxSize, 0), Vec3(0, 0, 2*boxSize));
context.setParameter(AndersenThermostat::Temperature(), temperature+10);
context.setState(s1);
State s3 = context.getState(State::Positions | State::Velocities | State::Parameters);
compareStates(s1, s3);
// Set the partial state and see if the correct things were set.
context.setState(s2);
State s4 = context.getState(State::Positions | State::Velocities | State::Parameters);
for (int i = 0; i < numParticles; i++) {
ASSERT_EQUAL_VEC(s2.getPositions()[i], s4.getPositions()[i], TOL);
ASSERT_EQUAL_VEC(s1.getVelocities()[i], s4.getVelocities()[i], TOL);
}
}
int main() {
try {
void runPlatformTests() {
testCheckpoint();
testSetState();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
}
platforms/reference/tests/TestReferenceCustomAngleForce.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2008-2010 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,122 +29,9 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of CustomAngleForce.
*/
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/CustomAngleForce.h"
#include "openmm/HarmonicAngleForce.h"
#include "openmm/System.h"
#include "openmm/VerletIntegrator.h"
#include "sfmt/SFMT.h"
#include <iostream>
#include <vector>
#include "ReferenceTests.h"
#include "TestCustomAngleForce.h"
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
void testAngles() {
// Create a system using a CustomAngleForce.
System customSystem;
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
CustomAngleForce* custom = new CustomAngleForce("scale*k*(theta-theta0)^2");
custom->addPerAngleParameter("theta0");
custom->addPerAngleParameter("k");
custom->addGlobalParameter("scale", 0.5);
vector<double> parameters(2);
parameters[0] = 1.5;
parameters[1] = 0.8;
custom->addAngle(0, 1, 2, parameters);
parameters[0] = 2.0;
parameters[1] = 0.5;
custom->addAngle(1, 2, 3, parameters);
customSystem.addForce(custom);
ASSERT(!custom->usesPeriodicBoundaryConditions());
ASSERT(!customSystem.usesPeriodicBoundaryConditions());
// Create an identical system using a HarmonicAngleForce.
System harmonicSystem;
harmonicSystem.addParticle(1.0);
harmonicSystem.addParticle(1.0);
harmonicSystem.addParticle(1.0);
harmonicSystem.addParticle(1.0);
HarmonicAngleForce* harmonic = new HarmonicAngleForce();
harmonic->addAngle(0, 1, 2, 1.5, 0.8);
harmonic->addAngle(1, 2, 3, 2.0, 0.5);
harmonicSystem.addForce(harmonic);
// Set the atoms in various positions, and verify that both systems give identical forces and energy.
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
vector<Vec3> positions(4);
VerletIntegrator integrator1(0.01);
VerletIntegrator integrator2(0.01);
Context c1(customSystem, integrator1, platform);
Context c2(harmonicSystem, integrator2, platform);
for (int i = 0; i < 10; i++) {
for (int j = 0; j < (int) positions.size(); j++)
positions[j] = Vec3(5.0*genrand_real2(sfmt), 5.0*genrand_real2(sfmt), 5.0*genrand_real2(sfmt));
c1.setPositions(positions);
c2.setPositions(positions);
State s1 = c1.getState(State::Forces | State::Energy);
State s2 = c2.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = s1.getForces();
for (int i = 0; i < customSystem.getNumParticles(); i++)
ASSERT_EQUAL_VEC(s1.getForces()[i], s2.getForces()[i], TOL);
ASSERT_EQUAL_TOL(s1.getPotentialEnergy(), s2.getPotentialEnergy(), TOL);
}
// Try changing the angle parameters and make sure it's still correct.
parameters[0] = 1.6;
parameters[1] = 0.9;
custom->setAngleParameters(0, 0, 1, 2, parameters);
parameters[0] = 2.1;
parameters[1] = 0.6;
custom->setAngleParameters(1, 1, 2, 3, parameters);
custom->updateParametersInContext(c1);
harmonic->setAngleParameters(0, 0, 1, 2, 1.6, 0.9);
harmonic->setAngleParameters(1, 1, 2, 3, 2.1, 0.6);
harmonic->updateParametersInContext(c2);
{
for (int j = 0; j < (int) positions.size(); j++)
positions[j] = Vec3(5.0*genrand_real2(sfmt), 5.0*genrand_real2(sfmt), 5.0*genrand_real2(sfmt));
c1.setPositions(positions);
c2.setPositions(positions);
State s1 = c1.getState(State::Forces | State::Energy);
State s2 = c2.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = s1.getForces();
for (int i = 0; i < customSystem.getNumParticles(); i++)
ASSERT_EQUAL_VEC(s1.getForces()[i], s2.getForces()[i], TOL);
ASSERT_EQUAL_TOL(s1.getPotentialEnergy(), s2.getPotentialEnergy(), TOL);
}
void runPlatformTests() {
}
int main() {
try {
testAngles();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
}
platforms/reference/tests/TestReferenceCustomBondForce.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2008-2009 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,90 +29,9 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of CustomBondForce.
*/
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/CustomBondForce.h"
#include "openmm/System.h"
#include "openmm/VerletIntegrator.h"
#include "SimTKOpenMMRealType.h"
#include <iostream>
#include <vector>
#include "ReferenceTests.h"
#include "TestCustomBondForce.h"
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
void testBonds() {
System system;
system.addParticle(1.0);
system.addParticle(1.0);
system.addParticle(1.0);
VerletIntegrator integrator(0.01);
CustomBondForce* forceField = new CustomBondForce("scale*k*(r-r0)^2");
forceField->addPerBondParameter("r0");
forceField->addPerBondParameter("k");
forceField->addGlobalParameter("scale", 0.5);
vector<double> parameters(2);
parameters[0] = 1.5;
parameters[1] = 0.8;
forceField->addBond(0, 1, parameters);
parameters[0] = 1.2;
parameters[1] = 0.7;
forceField->addBond(1, 2, parameters);
system.addForce(forceField);
ASSERT(!forceField->usesPeriodicBoundaryConditions());
ASSERT(!system.usesPeriodicBoundaryConditions());
Context context(system, integrator, platform);
vector<Vec3> positions(3);
positions[0] = Vec3(0, 2, 0);
positions[1] = Vec3(0, 0, 0);
positions[2] = Vec3(1, 0, 0);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
{
const vector<Vec3>& forces = state.getForces();
ASSERT_EQUAL_VEC(Vec3(0, -0.8*0.5, 0), forces[0], TOL);
ASSERT_EQUAL_VEC(Vec3(0.7*0.2, 0, 0), forces[2], TOL);
ASSERT_EQUAL_VEC(Vec3(-forces[0][0]-forces[2][0], -forces[0][1]-forces[2][1], -forces[0][2]-forces[2][2]), forces[1], TOL);
ASSERT_EQUAL_TOL(0.5*0.8*0.5*0.5 + 0.5*0.7*0.2*0.2, state.getPotentialEnergy(), TOL);
}
// Try changing the bond parameters and make sure it's still correct.
parameters[0] = 1.6;
parameters[1] = 0.9;
forceField->setBondParameters(0, 0, 1, parameters);
parameters[0] = 1.3;
parameters[1] = 0.8;
forceField->setBondParameters(1, 1, 2, parameters);
forceField->updateParametersInContext(context);
state = context.getState(State::Forces | State::Energy);
{
const vector<Vec3>& forces = state.getForces();
ASSERT_EQUAL_VEC(Vec3(0, -0.9*0.4, 0), forces[0], TOL);
ASSERT_EQUAL_VEC(Vec3(0.8*0.3, 0, 0), forces[2], TOL);
ASSERT_EQUAL_VEC(Vec3(-forces[0][0]-forces[2][0], -forces[0][1]-forces[2][1], -forces[0][2]-forces[2][2]), forces[1], TOL);
ASSERT_EQUAL_TOL(0.5*0.9*0.4*0.4 + 0.5*0.8*0.3*0.3, state.getPotentialEnergy(), TOL);
}
}
int main() {
try {
testBonds();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
void runPlatformTests() {
}
platforms/reference/tests/TestReferenceCustomCentroidBondForce.cpp
View file @ cecc774a
......@@ -29,246 +29,8 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of CustomCompoundBondForce.
*/
#include "ReferenceTests.h"
#include "TestCustomCentroidBondForce.h"
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/CustomCentroidBondForce.h"
#include "openmm/CustomCompoundBondForce.h"
#include "openmm/System.h"
#include "openmm/TabulatedFunction.h"
#include "openmm/VerletIntegrator.h"
#include "sfmt/SFMT.h"
#include <iostream>
#include <vector>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
void testHarmonicBond() {
System system;
system.addParticle(1.0);
system.addParticle(2.0);
system.addParticle(3.0);
system.addParticle(4.0);
system.addParticle(5.0);
CustomCentroidBondForce* force = new CustomCentroidBondForce(2, "k*distance(g1,g2)^2");
force->addPerBondParameter("k");
vector<int> particles1;
particles1.push_back(0);
particles1.push_back(1);
vector<int> particles2;
particles2.push_back(2);
particles2.push_back(3);
particles2.push_back(4);
force->addGroup(particles1);
force->addGroup(particles2);
vector<int> groups;
groups.push_back(0);
groups.push_back(1);
vector<double> parameters;
parameters.push_back(1.0);
force->addBond(groups, parameters);
system.addForce(force);
ASSERT(!system.usesPeriodicBoundaryConditions());
// The center of mass of group 0 is (1.5, 0, 0).
vector<Vec3> positions(5);
positions[0] = Vec3(2.5, 0, 0);
positions[1] = Vec3(1, 0, 0);
// The center of mass of group 1 is (-1, 0, 0).
positions[2] = Vec3(-6, 0, 0);
positions[3] = Vec3(-1, 0, 0);
positions[4] = Vec3(2, 0, 0);
// Check the forces and energy.
VerletIntegrator integrator(0.01);
Context context(system, integrator, platform);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
ASSERT_EQUAL_TOL(2.5*2.5, state.getPotentialEnergy(), TOL);
ASSERT_EQUAL_VEC(Vec3(-2*2.5*(1.0/3.0), 0, 0), state.getForces()[0], TOL);
ASSERT_EQUAL_VEC(Vec3(-2*2.5*(2.0/3.0), 0, 0), state.getForces()[1], TOL);
ASSERT_EQUAL_VEC(Vec3(2*2.5*(3.0/12.0), 0, 0), state.getForces()[2], TOL);
ASSERT_EQUAL_VEC(Vec3(2*2.5*(4.0/12.0), 0, 0), state.getForces()[3], TOL);
ASSERT_EQUAL_VEC(Vec3(2*2.5*(5.0/12.0), 0, 0), state.getForces()[4], TOL);
// Update the per-bond parameter and see if the results change.
parameters[0] = 2.0;
force->setBondParameters(0, groups, parameters);
force->updateParametersInContext(context);
state = context.getState(State::Forces | State::Energy);
ASSERT_EQUAL_TOL(2*2.5*2.5, state.getPotentialEnergy(), TOL);
ASSERT_EQUAL_VEC(Vec3(-4*2.5*(1.0/3.0), 0, 0), state.getForces()[0], TOL);
ASSERT_EQUAL_VEC(Vec3(-4*2.5*(2.0/3.0), 0, 0), state.getForces()[1], TOL);
ASSERT_EQUAL_VEC(Vec3(4*2.5*(3.0/12.0), 0, 0), state.getForces()[2], TOL);
ASSERT_EQUAL_VEC(Vec3(4*2.5*(4.0/12.0), 0, 0), state.getForces()[3], TOL);
ASSERT_EQUAL_VEC(Vec3(4*2.5*(5.0/12.0), 0, 0), state.getForces()[4], TOL);
// All the particles should be treated as a single molecule.
vector<std::vector<int> > molecules = context.getMolecules();
ASSERT_EQUAL(1, molecules.size());
ASSERT_EQUAL(5, molecules[0].size());
}
void testComplexFunction() {
int numParticles = 5;
System system;
for (int i = 0; i < numParticles; i++)
system.addParticle(2.0);
vector<double> table(20);
for (int i = 0; i < 20; i++)
table[i] = sin(0.11*i);
// When every group contains only one particle, a CustomCentroidBondForce is identical to a
// CustomCompoundBondForce. Use that to test a complicated energy function with lots of terms.
CustomCompoundBondForce* compound = new CustomCompoundBondForce(4, "x1+y2+z4+fn(distance(p1,p2))*angle(p3,p2,p4)+scale*dihedral(p2,p1,p4,p3)");
CustomCentroidBondForce* centroid = new CustomCentroidBondForce(4, "x1+y2+z4+fn(distance(g1,g2))*angle(g3,g2,g4)+scale*dihedral(g2,g1,g4,g3)");
compound->addGlobalParameter("scale", 0.5);
centroid->addGlobalParameter("scale", 0.5);
compound->addTabulatedFunction("fn", new Continuous1DFunction(table, -1, 10));
centroid->addTabulatedFunction("fn", new Continuous1DFunction(table, -1, 10));
// Add two bonds to the CustomCompoundBondForce.
vector<int> particles(4);
vector<double> parameters;
particles[0] = 0;
particles[1] = 1;
particles[2] = 2;
particles[3] = 3;
compound->addBond(particles, parameters);
particles[0] = 2;
particles[1] = 4;
particles[2] = 3;
particles[3] = 1;
compound->addBond(particles, parameters);
// Add identical bonds to the CustomCentroidBondForce. As a stronger test, make sure that
// group number is different from particle number.
vector<int> groupMembers(1);
groupMembers[0] = 3;
centroid->addGroup(groupMembers);
groupMembers[0] = 0;
centroid->addGroup(groupMembers);
groupMembers[0] = 1;
centroid->addGroup(groupMembers);
groupMembers[0] = 2;
centroid->addGroup(groupMembers);
groupMembers[0] = 4;
centroid->addGroup(groupMembers);
vector<int> groups(4);
groups[0] = 1;
groups[1] = 2;
groups[2] = 3;
groups[3] = 0;
centroid->addBond(groups, parameters);
groups[0] = 3;
groups[1] = 4;
groups[2] = 0;
groups[3] = 2;
centroid->addBond(groups, parameters);
// Add both forces as different force groups, and create a context.
centroid->setForceGroup(1);
system.addForce(compound);
system.addForce(centroid);
VerletIntegrator integrator(0.01);
Context context(system, integrator, platform);
// Evaluate the force and energy for various positions and see if they match.
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
vector<Vec3> positions(numParticles);
for (int i = 0; i < 10; i++) {
for (int j = 0; j < numParticles; j++)
positions[j] = Vec3(5.0*genrand_real2(sfmt), 5.0*genrand_real2(sfmt), 5.0*genrand_real2(sfmt));
context.setPositions(positions);
State state1 = context.getState(State::Forces | State::Energy, false, 1<<0);
State state2 = context.getState(State::Forces | State::Energy, false, 1<<1);
ASSERT_EQUAL_TOL(state1.getPotentialEnergy(), state2.getPotentialEnergy(), TOL);
for (int i = 0; i < numParticles; i++)
ASSERT_EQUAL_VEC(state1.getForces()[i], state2.getForces()[i], TOL);
}
}
void testCustomWeights() {
System system;
system.addParticle(1.0);
system.addParticle(2.0);
system.addParticle(3.0);
system.addParticle(4.0);
CustomCentroidBondForce* force = new CustomCentroidBondForce(2, "distance(g1,g2)^2");
vector<int> particles(2);
vector<double> weights(2);
particles[0] = 0;
particles[1] = 1;
weights[0] = 0.5;
weights[1] = 1.5;
force->addGroup(particles, weights);
particles[0] = 2;
particles[1] = 3;
weights[0] = 2.0;
weights[1] = 1.0;
force->addGroup(particles, weights);
vector<int> groups;
groups.push_back(0);
groups.push_back(1);
vector<double> parameters;
force->addBond(groups, parameters);
system.addForce(force);
// The center of mass of group 0 is (0, 1, 0).
vector<Vec3> positions(4);
positions[0] = Vec3(0, 4, 0);
positions[1] = Vec3(0, 0, 0);
// The center of mass of group 1 is (0, 10, 0).
positions[2] = Vec3(0, 9, 0);
positions[3] = Vec3(0, 12, 0);
// Check the forces and energy.
VerletIntegrator integrator(0.01);
Context context(system, integrator, platform);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
ASSERT_EQUAL_TOL(9.0*9.0, state.getPotentialEnergy(), TOL);
ASSERT_EQUAL_VEC(Vec3(0, 2*9*(0.5/2.0), 0), state.getForces()[0], TOL);
ASSERT_EQUAL_VEC(Vec3(0, 2*9*(1.5/2.0), 0), state.getForces()[1], TOL);
ASSERT_EQUAL_VEC(Vec3(0, -2*9*(2.0/3.0), 0), state.getForces()[2], TOL);
ASSERT_EQUAL_VEC(Vec3(0, -2*9*(1.0/3.0), 0), state.getForces()[3], TOL);
}
int main() {
try {
testHarmonicBond();
testComplexFunction();
testCustomWeights();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
void runPlatformTests() {
}
platforms/reference/tests/TestReferenceCustomCompoundBondForce.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2012-2015 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,306 +29,8 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of CustomCompoundBondForce.
*/
#include "ReferenceTests.h"
#include "TestCustomCompoundBondForce.h"
#ifdef WIN32
#define _USE_MATH_DEFINES // Needed to get M_PI
#endif
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/CustomCompoundBondForce.h"
#include "openmm/HarmonicAngleForce.h"
#include "openmm/HarmonicBondForce.h"
#include "openmm/PeriodicTorsionForce.h"
#include "openmm/System.h"
#include "openmm/VerletIntegrator.h"
#include "sfmt/SFMT.h"
#include <iostream>
#include <vector>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
void testBond() {
// Create a system using a CustomCompoundBondForce.
System customSystem;
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
CustomCompoundBondForce* custom = new CustomCompoundBondForce(4, "0.5*kb*((distance(p1,p2)-b0)^2+(distance(p2,p3)-b0)^2)+0.5*ka*(angle(p2,p3,p4)-a0)^2+kt*(1+cos(dihedral(p1,p2,p3,p4)-t0))");
custom->addPerBondParameter("kb");
custom->addPerBondParameter("ka");
custom->addPerBondParameter("kt");
custom->addPerBondParameter("b0");
custom->addPerBondParameter("a0");
custom->addPerBondParameter("t0");
vector<int> particles(4);
particles[0] = 0;
particles[1] = 1;
particles[2] = 3;
particles[3] = 2;
vector<double> parameters(6);
parameters[0] = 1.5;
parameters[1] = 0.8;
parameters[2] = 0.6;
parameters[3] = 1.1;
parameters[4] = 2.9;
parameters[5] = 1.3;
custom->addBond(particles, parameters);
customSystem.addForce(custom);
ASSERT(!custom->usesPeriodicBoundaryConditions());
ASSERT(!customSystem.usesPeriodicBoundaryConditions());
// Create an identical system using standard forces.
System standardSystem;
standardSystem.addParticle(1.0);
standardSystem.addParticle(1.0);
standardSystem.addParticle(1.0);
standardSystem.addParticle(1.0);
HarmonicBondForce* bonds = new HarmonicBondForce();
bonds->addBond(0, 1, 1.1, 1.5);
bonds->addBond(1, 3, 1.1, 1.5);
standardSystem.addForce(bonds);
HarmonicAngleForce* angles = new HarmonicAngleForce();
angles->addAngle(1, 3, 2, 2.9, 0.8);
standardSystem.addForce(angles);
PeriodicTorsionForce* torsions = new PeriodicTorsionForce();
torsions->addTorsion(0, 1, 3, 2, 1, 1.3, 0.6);
standardSystem.addForce(torsions);
// Set the atoms in various positions, and verify that both systems give identical forces and energy.
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
VerletIntegrator integrator1(0.01);
VerletIntegrator integrator2(0.01);
Context c1(customSystem, integrator1, platform);
Context c2(standardSystem, integrator2, platform);
vector<Vec3> positions(4);
for (int i = 0; i < 10; i++) {
for (int j = 0; j < (int) positions.size(); j++)
positions[j] = Vec3(5.0*genrand_real2(sfmt), 5.0*genrand_real2(sfmt), 5.0*genrand_real2(sfmt));
c1.setPositions(positions);
c2.setPositions(positions);
State s1 = c1.getState(State::Forces | State::Energy);
State s2 = c2.getState(State::Forces | State::Energy);
for (int i = 0; i < customSystem.getNumParticles(); i++)
ASSERT_EQUAL_VEC(s1.getForces()[i], s2.getForces()[i], TOL);
ASSERT_EQUAL_TOL(s1.getPotentialEnergy(), s2.getPotentialEnergy(), TOL);
}
// Try changing the bond parameters and make sure it's still correct.
parameters[0] = 1.6;
parameters[3] = 1.3;
custom->setBondParameters(0, particles, parameters);
custom->updateParametersInContext(c1);
bonds->setBondParameters(0, 0, 1, 1.3, 1.6);
bonds->setBondParameters(1, 1, 3, 1.3, 1.6);
bonds->updateParametersInContext(c2);
{
State s1 = c1.getState(State::Forces | State::Energy);
State s2 = c2.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = s1.getForces();
for (int i = 0; i < customSystem.getNumParticles(); i++)
ASSERT_EQUAL_VEC(s1.getForces()[i], s2.getForces()[i], TOL);
ASSERT_EQUAL_TOL(s1.getPotentialEnergy(), s2.getPotentialEnergy(), TOL);
}
}
void testPositionDependence() {
System customSystem;
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
CustomCompoundBondForce* custom = new CustomCompoundBondForce(2, "scale1*distance(p1,p2)+scale2*x1+2*y2");
custom->addGlobalParameter("scale1", 0.3);
custom->addGlobalParameter("scale2", 0.2);
vector<int> particles(2);
particles[0] = 1;
particles[1] = 0;
vector<double> parameters;
custom->addBond(particles, parameters);
customSystem.addForce(custom);
vector<Vec3> positions(2);
positions[0] = Vec3(1.5, 1, 0);
positions[1] = Vec3(0.5, 1, 0);
VerletIntegrator integrator(0.01);
Context context(customSystem, integrator, platform);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
ASSERT_EQUAL_TOL(0.3*1.0+0.2*0.5+2*1, state.getPotentialEnergy(), 1e-5);
ASSERT_EQUAL_VEC(Vec3(-0.3, -2, 0), state.getForces()[0], 1e-5);
ASSERT_EQUAL_VEC(Vec3(0.3-0.2, 0, 0), state.getForces()[1], 1e-5);
}
void testContinuous2DFunction() {
const int xsize = 10;
const int ysize = 11;
const double xmin = 0.4;
const double xmax = 1.1;
const double ymin = 0.0;
const double ymax = 0.9;
System system;
system.addParticle(1.0);
VerletIntegrator integrator(0.01);
CustomCompoundBondForce* forceField = new CustomCompoundBondForce(1, "fn(x1,y1)+1");
vector<int> particles(1, 0);
forceField->addBond(particles, vector<double>());
vector<double> table(xsize*ysize);
for (int i = 0; i < xsize; i++) {
for (int j = 0; j < ysize; j++) {
double x = xmin + i*(xmax-xmin)/xsize;
double y = ymin + j*(ymax-ymin)/ysize;
table[i+xsize*j] = sin(0.25*x)*cos(0.33*y);
}
}
forceField->addTabulatedFunction("fn", new Continuous2DFunction(xsize, ysize, table, xmin, xmax, ymin, ymax));
system.addForce(forceField);
Context context(system, integrator, platform);
vector<Vec3> positions(1);
for (double x = xmin-0.15; x < xmax+0.2; x += 0.1) {
for (double y = ymin-0.15; y < ymax+0.2; y += 0.1) {
positions[0] = Vec3(x, y, 1.5);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = state.getForces();
double energy = 1;
Vec3 force(0, 0, 0);
if (x >= xmin && x <= xmax && y >= ymin && y <= ymax) {
energy = sin(0.25*x)*cos(0.33*y)+1;
force[0] = -0.25*cos(0.25*x)*cos(0.33*y);
force[1] = 0.3*sin(0.25*x)*sin(0.33*y);
}
ASSERT_EQUAL_VEC(force, forces[0], 0.1);
ASSERT_EQUAL_TOL(energy, state.getPotentialEnergy(), 0.05);
}
}
}
void testContinuous3DFunction() {
const int xsize = 10;
const int ysize = 11;
const int zsize = 12;
const double xmin = 0.4;
const double xmax = 1.1;
const double ymin = 0.0;
const double ymax = 0.9;
const double zmin = 0.2;
const double zmax = 1.3;
System system;
system.addParticle(1.0);
VerletIntegrator integrator(0.01);
CustomCompoundBondForce* forceField = new CustomCompoundBondForce(1, "fn(x1,y1,z1)+1");
vector<int> particles(1, 0);
forceField->addBond(particles, vector<double>());
vector<double> table(xsize*ysize*zsize);
for (int i = 0; i < xsize; i++) {
for (int j = 0; j < ysize; j++) {
for (int k = 0; k < zsize; k++) {
double x = xmin + i*(xmax-xmin)/xsize;
double y = ymin + j*(ymax-ymin)/ysize;
double z = zmin + k*(zmax-zmin)/zsize;
table[i+xsize*j+xsize*ysize*k] = sin(0.25*x)*cos(0.33*y)*(1+z);
}
}
}
forceField->addTabulatedFunction("fn", new Continuous3DFunction(xsize, ysize, zsize, table, xmin, xmax, ymin, ymax, zmin, zmax));
system.addForce(forceField);
Context context(system, integrator, platform);
vector<Vec3> positions(1);
for (double x = xmin-0.15; x < xmax+0.2; x += 0.1) {
for (double y = ymin-0.15; y < ymax+0.2; y += 0.1) {
for (double z = zmin-0.15; z < zmax+0.2; z += 0.1) {
positions[0] = Vec3(x, y, z);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = state.getForces();
double energy = 1;
Vec3 force(0, 0, 0);
if (x >= xmin && x <= xmax && y >= ymin && y <= ymax && z >= zmin && z <= zmax) {
energy = sin(0.25*x)*cos(0.33*y)*(1.0+z)+1;
force[0] = -0.25*cos(0.25*x)*cos(0.33*y)*(1.0+z);
force[1] = 0.3*sin(0.25*x)*sin(0.33*y)*(1.0+z);
force[2] = -sin(0.25*x)*cos(0.33*y);
}
ASSERT_EQUAL_VEC(force, forces[0], 0.1);
ASSERT_EQUAL_TOL(energy, state.getPotentialEnergy(), 0.05);
}
}
}
}
void testMultipleBonds() {
// Two compound bonds using Urey-Bradley example from API doc
System customSystem;
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
CustomCompoundBondForce* custom = new CustomCompoundBondForce(3,
"0.5*(kangle*(angle(p1,p2,p3)-theta0)^2+kbond*(distance(p1,p3)-r0)^2)");
custom->addPerBondParameter("kangle");
custom->addPerBondParameter("kbond");
custom->addPerBondParameter("theta0");
custom->addPerBondParameter("r0");
vector<double> parameters(4);
parameters[0] = 1.0;
parameters[1] = 1.0;
parameters[2] = 2 * M_PI / 3;
parameters[3] = sqrt(3.0) / 2;
vector<int> particles0(3);
particles0[0] = 0;
particles0[1] = 1;
particles0[2] = 2;
vector<int> particles1(3);
particles1[0] = 1;
particles1[1] = 2;
particles1[2] = 3;
custom->addBond(particles0, parameters);
custom->addBond(particles1, parameters);
customSystem.addForce(custom);
vector<Vec3> positions(4);
positions[0] = Vec3(0, 0.5, 0);
positions[1] = Vec3(0, 0, 0);
positions[2] = Vec3(0.5, 0, 0);
positions[3] = Vec3(0.6, 0, 0.4);
VerletIntegrator integrator(0.01);
Context context(customSystem, integrator, platform);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
ASSERT_EQUAL_TOL(0.199, state.getPotentialEnergy(), 1e-3);
vector<Vec3> forces(state.getForces());
ASSERT_EQUAL_VEC(Vec3(-1.160, 0.112, 0.0), forces[0], 1e-3);
ASSERT_EQUAL_VEC(Vec3(0.927, 1.047, -0.638), forces[1], 1e-3);
ASSERT_EQUAL_VEC(Vec3(-0.543, -1.160, 0.721), forces[2], 1e-3);
ASSERT_EQUAL_VEC(Vec3(0.776, 0.0, -0.084), forces[3], 1e-3);
}
int main() {
try {
testBond();
testPositionDependence();
testContinuous2DFunction();
testContinuous3DFunction();
testMultipleBonds();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
void runPlatformTests() {
}
platforms/reference/tests/TestReferenceCustomExternalForce.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2008-2009 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,88 +29,8 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of CustomExternalForce.
*/
#include "ReferenceTests.h"
#include "TestCustomExternalForce.h"
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/CustomExternalForce.h"
#include "openmm/System.h"
#include "openmm/VerletIntegrator.h"
#include "SimTKOpenMMRealType.h"
#include <iostream>
#include <vector>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
void testForce() {
System system;
system.addParticle(1.0);
system.addParticle(1.0);
system.addParticle(1.0);
VerletIntegrator integrator(0.01);
CustomExternalForce* forceField = new CustomExternalForce("scale*(x+yscale*(y-y0)^2)");
forceField->addPerParticleParameter("y0");
forceField->addPerParticleParameter("yscale");
forceField->addGlobalParameter("scale", 0.5);
vector<double> parameters(2);
parameters[0] = 0.5;
parameters[1] = 2.0;
forceField->addParticle(0, parameters);
parameters[0] = 1.5;
parameters[1] = 3.0;
forceField->addParticle(2, parameters);
system.addForce(forceField);
ASSERT(!forceField->usesPeriodicBoundaryConditions());
ASSERT(!system.usesPeriodicBoundaryConditions());
Context context(system, integrator, platform);
vector<Vec3> positions(3);
positions[0] = Vec3(0, 2, 0);
positions[1] = Vec3(0, 0, 1);
positions[2] = Vec3(1, 0, 1);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
{
const vector<Vec3>& forces = state.getForces();
ASSERT_EQUAL_VEC(Vec3(-0.5, -0.5*2.0*2.0*1.5, 0), forces[0], TOL);
ASSERT_EQUAL_VEC(Vec3(0, 0, 0), forces[1], TOL);
ASSERT_EQUAL_VEC(Vec3(-0.5, 0.5*3.0*2.0*1.5, 0), forces[2], TOL);
ASSERT_EQUAL_TOL(0.5*(1.0 + 2.0*1.5*1.5 + 3.0*1.5*1.5), state.getPotentialEnergy(), TOL);
}
// Try changing the parameters and make sure it's still correct.
parameters[0] = 1.4;
parameters[1] = 3.5;
forceField->setParticleParameters(1, 2, parameters);
forceField->updateParametersInContext(context);
state = context.getState(State::Forces | State::Energy);
{
const vector<Vec3>& forces = state.getForces();
ASSERT_EQUAL_VEC(Vec3(-0.5, -0.5*2.0*2.0*1.5, 0), forces[0], TOL);
ASSERT_EQUAL_VEC(Vec3(0, 0, 0), forces[1], TOL);
ASSERT_EQUAL_VEC(Vec3(-0.5, 0.5*3.5*2.0*1.4, 0), forces[2], TOL);
ASSERT_EQUAL_TOL(0.5*(1.0 + 2.0*1.5*1.5 + 3.5*1.4*1.4), state.getPotentialEnergy(), TOL);
}
}
int main() {
try {
testForce();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
void runPlatformTests() {
}
platforms/reference/tests/TestReferenceCustomGBForce.cpp
View file @ cecc774a
/* -------------------------------------------------------------------------- *
* OpenMM *
* -------------------------------------------------------------------------- *
......@@ -7,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2008-2013 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -30,882 +29,8 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests all the different force terms in the reference implementation of CustomGBForce.
*/
#include "openmm/internal/AssertionUtilities.h"
#include "sfmt/SFMT.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/CustomGBForce.h"
#include "openmm/GBSAOBCForce.h"
#include "openmm/GBVIForce.h"
#include "openmm/OpenMMException.h"
#include "openmm/System.h"
#include "openmm/VerletIntegrator.h"
#include <iostream>
#include <vector>
#include <algorithm>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
void testOBC(GBSAOBCForce::NonbondedMethod obcMethod, CustomGBForce::NonbondedMethod customMethod) {
const int numMolecules = 70;
const int numParticles = numMolecules*2;
const double boxSize = 10.0;
const double cutoff = 2.0;
// Create two systems: one with a GBSAOBCForce, and one using a CustomGBForce to implement the same interaction.
System standardSystem;
System customSystem;
for (int i = 0; i < numParticles; i++) {
standardSystem.addParticle(1.0);
customSystem.addParticle(1.0);
}
standardSystem.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0.0, 0.0), Vec3(0.0, boxSize, 0.0), Vec3(0.0, 0.0, boxSize));
customSystem.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0.0, 0.0), Vec3(0.0, boxSize, 0.0), Vec3(0.0, 0.0, boxSize));
GBSAOBCForce* obc = new GBSAOBCForce();
CustomGBForce* custom = new CustomGBForce();
obc->setCutoffDistance(cutoff);
custom->setCutoffDistance(cutoff);
custom->addPerParticleParameter("q");
custom->addPerParticleParameter("radius");
custom->addPerParticleParameter("scale");
custom->addGlobalParameter("solventDielectric", obc->getSolventDielectric());
custom->addGlobalParameter("soluteDielectric", obc->getSoluteDielectric());
custom->addComputedValue("I", "step(r+sr2-or1)*0.5*(1/L-1/U+0.25*(1/U^2-1/L^2)*(r-sr2*sr2/r)+0.5*log(L/U)/r+C);"
"U=r+sr2;"
"C=2*(1/or1-1/L)*step(sr2-r-or1);"
"L=max(or1, D);"
"D=abs(r-sr2);"
"sr2 = scale2*or2;"
"or1 = radius1-0.009; or2 = radius2-0.009", CustomGBForce::ParticlePairNoExclusions);
custom->addComputedValue("B", "1/(1/or-tanh(1*psi-0.8*psi^2+4.85*psi^3)/radius);"
"psi=I*or; or=radius-0.009", CustomGBForce::SingleParticle);
custom->addEnergyTerm("28.3919551*(radius+0.14)^2*(radius/B)^6-0.5*138.935485*(1/soluteDielectric-1/solventDielectric)*q^2/B", CustomGBForce::SingleParticle);
string invCutoffString = "";
if (obcMethod != GBSAOBCForce::NoCutoff) {
stringstream s;
s<<(1.0/cutoff);
invCutoffString = s.str();
}
custom->addEnergyTerm("138.935485*(1/soluteDielectric-1/solventDielectric)*q1*q2*("+invCutoffString+"-1/f);"
"f=sqrt(r^2+B1*B2*exp(-r^2/(4*B1*B2)))", CustomGBForce::ParticlePairNoExclusions);
vector<Vec3> positions(numParticles);
vector<Vec3> velocities(numParticles);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
vector<double> params(3);
for (int i = 0; i < numMolecules; i++) {
if (i < numMolecules/2) {
obc->addParticle(1.0, 0.2, 0.5);
params[0] = 1.0;
params[1] = 0.2;
params[2] = 0.5;
custom->addParticle(params);
obc->addParticle(-1.0, 0.1, 0.5);
params[0] = -1.0;
params[1] = 0.1;
custom->addParticle(params);
}
else {
obc->addParticle(1.0, 0.2, 0.8);
params[0] = 1.0;
params[1] = 0.2;
params[2] = 0.8;
custom->addParticle(params);
obc->addParticle(-1.0, 0.1, 0.8);
params[0] = -1.0;
params[1] = 0.1;
custom->addParticle(params);
}
positions[2*i] = Vec3(boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt));
positions[2*i+1] = Vec3(positions[2*i][0]+1.0, positions[2*i][1], positions[2*i][2]);
velocities[2*i] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt));
velocities[2*i+1] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt));
}
obc->setNonbondedMethod(obcMethod);
custom->setNonbondedMethod(customMethod);
standardSystem.addForce(obc);
customSystem.addForce(custom);
if (customMethod == CustomGBForce::CutoffPeriodic) {
ASSERT(custom->usesPeriodicBoundaryConditions());
ASSERT(obc->usesPeriodicBoundaryConditions());
ASSERT(standardSystem.usesPeriodicBoundaryConditions());
ASSERT(customSystem.usesPeriodicBoundaryConditions());
}
else {
ASSERT(!custom->usesPeriodicBoundaryConditions());
ASSERT(!obc->usesPeriodicBoundaryConditions());
ASSERT(!standardSystem.usesPeriodicBoundaryConditions());
ASSERT(!customSystem.usesPeriodicBoundaryConditions());
}
VerletIntegrator integrator1(0.01);
VerletIntegrator integrator2(0.01);
Context context1(standardSystem, integrator1, platform);
context1.setPositions(positions);
context1.setVelocities(velocities);
State state1 = context1.getState(State::Forces | State::Energy);
Context context2(customSystem, integrator2, platform);
context2.setPositions(positions);
context2.setVelocities(velocities);
State state2 = context2.getState(State::Forces | State::Energy);
ASSERT_EQUAL_TOL(state1.getPotentialEnergy(), state2.getPotentialEnergy(), 1e-4);
for (int i = 0; i < numParticles; i++) {
ASSERT_EQUAL_VEC(state1.getForces()[i], state2.getForces()[i], 1e-4);
}
// Try changing the particle parameters and make sure it's still correct.
for (int i = 0; i < numMolecules/2; i++) {
obc->setParticleParameters(2*i, 1.1, 0.3, 0.6);
params[0] = 1.1;
params[1] = 0.3;
params[2] = 0.6;
custom->setParticleParameters(2*i, params);
obc->setParticleParameters(2*i+1, -1.1, 0.2, 0.4);
params[0] = -1.1;
params[1] = 0.2;
params[2] = 0.4;
custom->setParticleParameters(2*i+1, params);
}
obc->updateParametersInContext(context1);
custom->updateParametersInContext(context2);
state1 = context1.getState(State::Forces | State::Energy);
state2 = context2.getState(State::Forces | State::Energy);
ASSERT_EQUAL_TOL(state1.getPotentialEnergy(), state2.getPotentialEnergy(), 1e-4);
for (int i = 0; i < numParticles; i++) {
ASSERT_EQUAL_VEC(state1.getForces()[i], state2.getForces()[i], 1e-4);
}
}
void testMembrane() {
const int numMolecules = 70;
const int numParticles = numMolecules*2;
const double boxSize = 10.0;
// Create a system with an implicit membrane.
System system;
for (int i = 0; i < numParticles; i++) {
system.addParticle(1.0);
}
system.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0.0, 0.0), Vec3(0.0, boxSize, 0.0), Vec3(0.0, 0.0, boxSize));
CustomGBForce* custom = new CustomGBForce();
custom->setCutoffDistance(2.0);
custom->addPerParticleParameter("q");
custom->addPerParticleParameter("radius");
custom->addPerParticleParameter("scale");
custom->addGlobalParameter("thickness", 3);
custom->addGlobalParameter("solventDielectric", 78.3);
custom->addGlobalParameter("soluteDielectric", 1);
custom->addComputedValue("Imol", "step(r+sr2-or1)*0.5*(1/L-1/U+0.25*(1/U^2-1/L^2)*(r-sr2*sr2/r)+0.5*log(L/U)/r+C);"
"U=r+sr2;"
"C=2*(1/or1-1/L)*step(sr2-r-or1);"
"L=max(or1, D);"
"D=abs(r-sr2);"
"sr2 = scale2*or2;"
"or1 = radius1-0.009; or2 = radius2-0.009", CustomGBForce::ParticlePairNoExclusions);
custom->addComputedValue("Imem", "(1/radius+2*log(2)/thickness)/(1+exp(7.2*(abs(z)+radius-0.5*thickness)))", CustomGBForce::SingleParticle);
custom->addComputedValue("B", "1/(1/or-tanh(1*psi-0.8*psi^2+4.85*psi^3)/radius);"
"psi=max(Imol,Imem)*or; or=radius-0.009", CustomGBForce::SingleParticle);
custom->addEnergyTerm("28.3919551*(radius+0.14)^2*(radius/B)^6-0.5*138.935456*(1/soluteDielectric-1/solventDielectric)*q^2/B", CustomGBForce::SingleParticle);
custom->addEnergyTerm("-138.935456*(1/soluteDielectric-1/solventDielectric)*q1*q2/f;"
"f=sqrt(r^2+B1*B2*exp(-r^2/(4*B1*B2)))", CustomGBForce::ParticlePairNoExclusions);
vector<Vec3> positions(numParticles);
vector<Vec3> velocities(numParticles);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
vector<double> params(3);
for (int i = 0; i < numMolecules; i++) {
if (i < numMolecules/2) {
params[0] = 1.0;
params[1] = 0.2;
params[2] = 0.5;
custom->addParticle(params);
params[0] = -1.0;
params[1] = 0.1;
custom->addParticle(params);
}
else {
params[0] = 1.0;
params[1] = 0.2;
params[2] = 0.8;
custom->addParticle(params);
params[0] = -1.0;
params[1] = 0.1;
custom->addParticle(params);
}
positions[2*i] = Vec3(boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt));
positions[2*i+1] = Vec3(positions[2*i][0]+1.0, positions[2*i][1], positions[2*i][2]);
velocities[2*i] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt));
velocities[2*i+1] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt));
}
system.addForce(custom);
VerletIntegrator integrator(0.01);
Context context(system, integrator, platform);
context.setPositions(positions);
context.setVelocities(velocities);
State state = context.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = state.getForces();
// Take a small step in the direction of the energy gradient and see whether the potential energy changes by the expected amount.
double norm = 0.0;
for (int i = 0; i < (int) forces.size(); ++i)
norm += forces[i].dot(forces[i]);
norm = std::sqrt(norm);
const double stepSize = 1e-2;
double step = 0.5*stepSize/norm;
vector<Vec3> positions2(numParticles), positions3(numParticles);
for (int i = 0; i < (int) positions.size(); ++i) {
Vec3 p = positions[i];
Vec3 f = forces[i];
positions2[i] = Vec3(p[0]-f[0]*step, p[1]-f[1]*step, p[2]-f[2]*step);
positions3[i] = Vec3(p[0]+f[0]*step, p[1]+f[1]*step, p[2]+f[2]*step);
}
context.setPositions(positions2);
State state2 = context.getState(State::Energy);
context.setPositions(positions3);
State state3 = context.getState(State::Energy);
ASSERT_EQUAL_TOL(norm, (state2.getPotentialEnergy()-state3.getPotentialEnergy())/stepSize, 1e-3);
}
void testTabulatedFunction() {
System system;
system.addParticle(1.0);
system.addParticle(1.0);
VerletIntegrator integrator(0.01);
CustomGBForce* force = new CustomGBForce();
force->addComputedValue("a", "0", CustomGBForce::ParticlePair);
force->addEnergyTerm("fn(r)+1", CustomGBForce::ParticlePair);
force->addParticle(vector<double>());
force->addParticle(vector<double>());
vector<double> table;
for (int i = 0; i < 21; i++)
table.push_back(std::sin(0.25*i));
force->addTabulatedFunction("fn", new Continuous1DFunction(table, 1.0, 6.0));
system.addForce(force);
Context context(system, integrator, platform);
vector<Vec3> positions(2);
positions[0] = Vec3(0, 0, 0);
for (int i = 1; i < 30; i++) {
double x = (7.0/30.0)*i;
positions[1] = Vec3(x, 0, 0);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = state.getForces();
double force = (x < 1.0 || x > 6.0 ? 0.0 : -std::cos(x-1.0));
double energy = (x < 1.0 || x > 6.0 ? 0.0 : std::sin(x-1.0))+1.0;
ASSERT_EQUAL_VEC(Vec3(-force, 0, 0), forces[0], 0.1);
ASSERT_EQUAL_VEC(Vec3(force, 0, 0), forces[1], 0.1);
ASSERT_EQUAL_TOL(energy, state.getPotentialEnergy(), 0.02);
}
}
void testMultipleChainRules() {
System system;
system.addParticle(1.0);
system.addParticle(1.0);
VerletIntegrator integrator(0.01);
CustomGBForce* force = new CustomGBForce();
force->addComputedValue("a", "2*r", CustomGBForce::ParticlePair);
force->addComputedValue("b", "a+1", CustomGBForce::SingleParticle);
force->addComputedValue("c", "2*b+a", CustomGBForce::SingleParticle);
force->addEnergyTerm("0.1*a+1*b+10*c", CustomGBForce::SingleParticle); // 0.1*(2*r) + 2*r+1 + 10*(3*a+2) = 0.2*r + 2*r+1 + 40*r+20+20*r = 62.2*r+21
force->addParticle(vector<double>());
force->addParticle(vector<double>());
system.addForce(force);
Context context(system, integrator, platform);
vector<Vec3> positions(2);
positions[0] = Vec3(0, 0, 0);
for (int i = 1; i < 5; i++) {
positions[1] = Vec3(i, 0, 0);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = state.getForces();
ASSERT_EQUAL_VEC(Vec3(124.4, 0, 0), forces[0], 1e-4);
ASSERT_EQUAL_VEC(Vec3(-124.4, 0, 0), forces[1], 1e-4);
ASSERT_EQUAL_TOL(2*(62.2*i+21), state.getPotentialEnergy(), 0.02);
}
}
void testPositionDependence() {
System system;
system.addParticle(1.0);
system.addParticle(1.0);
VerletIntegrator integrator(0.01);
CustomGBForce* force = new CustomGBForce();
force->addComputedValue("a", "r", CustomGBForce::ParticlePair);
force->addComputedValue("b", "a+x*y", CustomGBForce::SingleParticle);
force->addEnergyTerm("b*z", CustomGBForce::SingleParticle);
force->addEnergyTerm("b1+b2", CustomGBForce::ParticlePair); // = 2*r+x1*y1+x2*y2
force->addParticle(vector<double>());
force->addParticle(vector<double>());
system.addForce(force);
Context context(system, integrator, platform);
vector<Vec3> positions(2);
vector<Vec3> forces(2);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
for (int i = 0; i < 5; i++) {
positions[0] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt));
positions[1] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt));
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = state.getForces();
Vec3 delta = positions[0]-positions[1];
double r = sqrt(delta.dot(delta));
double energy = 2*r+positions[0][0]*positions[0][1]+positions[1][0]*positions[1][1];
for (int j = 0; j < 2; j++)
energy += positions[j][2]*(r+positions[j][0]*positions[j][1]);
Vec3 force1(-(1+positions[0][2])*delta[0]/r-(1+positions[0][2])*positions[0][1]-(1+positions[1][2])*delta[0]/r,
-(1+positions[0][2])*delta[1]/r-(1+positions[0][2])*positions[0][0]-(1+positions[1][2])*delta[1]/r,
-(1+positions[0][2])*delta[2]/r-(r+positions[0][0]*positions[0][1])-(1+positions[1][2])*delta[2]/r);
Vec3 force2((1+positions[0][2])*delta[0]/r+(1+positions[1][2])*delta[0]/r-(1+positions[1][2])*positions[1][1],
(1+positions[0][2])*delta[1]/r+(1+positions[1][2])*delta[1]/r-(1+positions[1][2])*positions[1][0],
(1+positions[0][2])*delta[2]/r+(1+positions[1][2])*delta[2]/r-(r+positions[1][0]*positions[1][1]));
ASSERT_EQUAL_VEC(force1, forces[0], 1e-4);
ASSERT_EQUAL_VEC(force2, forces[1], 1e-4);
ASSERT_EQUAL_TOL(energy, state.getPotentialEnergy(), 0.02);
// Take a small step in the direction of the energy gradient and see whether the potential energy changes by the expected amount.
double norm = 0.0;
for (int i = 0; i < (int) forces.size(); ++i)
norm += forces[i].dot(forces[i]);
norm = std::sqrt(norm);
const double stepSize = 1e-3;
double step = 0.5*stepSize/norm;
vector<Vec3> positions2(2), positions3(2);
for (int i = 0; i < (int) positions.size(); ++i) {
Vec3 p = positions[i];
Vec3 f = forces[i];
positions2[i] = Vec3(p[0]-f[0]*step, p[1]-f[1]*step, p[2]-f[2]*step);
positions3[i] = Vec3(p[0]+f[0]*step, p[1]+f[1]*step, p[2]+f[2]*step);
}
context.setPositions(positions2);
State state2 = context.getState(State::Energy);
context.setPositions(positions3);
State state3 = context.getState(State::Energy);
ASSERT_EQUAL_TOL(norm, (state2.getPotentialEnergy()-state3.getPotentialEnergy())/stepSize, 1e-3);
}
}
void testExclusions() {
for (int i = 3; i < 4; i++) {
System system;
system.addParticle(1.0);
system.addParticle(1.0);
VerletIntegrator integrator(0.01);
CustomGBForce* force = new CustomGBForce();
force->addComputedValue("a", "r", i < 2 ? CustomGBForce::ParticlePair : CustomGBForce::ParticlePairNoExclusions);
force->addEnergyTerm("a", CustomGBForce::SingleParticle);
force->addEnergyTerm("(1+a1+a2)*r", i%2 == 0 ? CustomGBForce::ParticlePair : CustomGBForce::ParticlePairNoExclusions);
force->addParticle(vector<double>());
force->addParticle(vector<double>());
force->addExclusion(0, 1);
system.addForce(force);
Context context(system, integrator, platform);
vector<Vec3> positions(2);
positions[0] = Vec3(0, 0, 0);
positions[1] = Vec3(1, 0, 0);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = state.getForces();
double f, energy;
switch (i)
{
case 0: // e = 0
f = 0;
energy = 0;
break;
case 1: // e = r
f = 1;
energy = 1;
break;
case 2: // e = 2r
f = 2;
energy = 2;
break;
case 3: // e = 3r + 2r^2
f = 7;
energy = 5;
break;
default:
ASSERT(false);
}
ASSERT_EQUAL_VEC(Vec3(f, 0, 0), forces[0], 1e-4);
ASSERT_EQUAL_VEC(Vec3(-f, 0, 0), forces[1], 1e-4);
ASSERT_EQUAL_TOL(energy, state.getPotentialEnergy(), 1e-4);
// Take a small step in the direction of the energy gradient and see whether the potential energy changes by the expected amount.
double norm = 0.0;
for (int i = 0; i < (int) forces.size(); ++i)
norm += forces[i].dot(forces[i]);
norm = std::sqrt(norm);
const double stepSize = 1e-3;
double step = stepSize/norm;
for (int i = 0; i < (int) positions.size(); ++i) {
Vec3 p = positions[i];
Vec3 f = forces[i];
positions[i] = Vec3(p[0]-f[0]*step, p[1]-f[1]*step, p[2]-f[2]*step);
}
context.setPositions(positions);
State state2 = context.getState(State::Energy);
ASSERT_EQUAL_TOL(norm, (state2.getPotentialEnergy()-state.getPotentialEnergy())/stepSize, 1e-3*abs(state.getPotentialEnergy()));
}
}
// create custom GB/VI force
static CustomGBForce* createCustomGBVI(double solventDielectric, double soluteDielectric) {
CustomGBForce* customGbviForce = new CustomGBForce();
customGbviForce->setCutoffDistance(2.0);
customGbviForce->addPerParticleParameter("q");
customGbviForce->addPerParticleParameter("radius");
customGbviForce->addPerParticleParameter("scaleFactor"); // derived in GBVIForce implmentation, but parameter here
customGbviForce->addPerParticleParameter("gamma");
customGbviForce->addGlobalParameter("solventDielectric", solventDielectric);
customGbviForce->addGlobalParameter("soluteDielectric", soluteDielectric);
customGbviForce->addComputedValue("V", " uL - lL + factor3/(radius1*radius1*radius1);"
"uL = 1.5*x2uI*(0.25*rI-0.33333*xuI+0.125*(r2-S2)*rI*x2uI);"
"lL = 1.5*x2lI*(0.25*rI-0.33333*xlI+0.125*(r2-S2)*rI*x2lI);"
"x2lI = 1.0/(xl*xl);"
"xlI = 1.0/(xl);"
"xuI = 1.0/(xu);"
"x2uI = 1.0/(xu*xu);"
"xu = (r+scaleFactor2);"
"rI = 1.0/(r);"
"r2 = (r*r);"
"xl = factor1*lMax + factor2*xuu + factor3*(r-scaleFactor2);"
"xuu = (r+scaleFactor2);"
"S2 = (scaleFactor2*scaleFactor2);"
"factor1 = step(r-absRadiusScaleDiff);"
"absRadiusScaleDiff = abs(radiusScaleDiff);"
"radiusScaleDiff = (radius1-scaleFactor2);"
"factor2 = step(radius1-scaleFactor2-r);"
"factor3 = step(scaleFactor2-radius1-r);"
"lMax = max(radius1,r-scaleFactor2);"
, CustomGBForce::ParticlePairNoExclusions);
customGbviForce->addComputedValue("B", "(1.0/(radius*radius*radius)-V)^(-0.33333333)", CustomGBForce::SingleParticle);
// nonpolar term + polar self energy
customGbviForce->addEnergyTerm("(-138.935485*0.5*((1.0/soluteDielectric)-(1.0/solventDielectric))*q^2/B)-((1.0/soluteDielectric)-(1.0/solventDielectric))*((gamma*(radius/B)^3))", CustomGBForce::SingleParticle);
// polar pair energy
customGbviForce->addEnergyTerm("-138.935485*(1/soluteDielectric-1/solventDielectric)*q1*q2/f;"
"f=sqrt(r^2+B1*B2*exp(-r^2/(4*B1*B2)))", CustomGBForce::ParticlePairNoExclusions);
return customGbviForce;
}
// ethance GB/VI test case
static void buildEthane(GBVIForce* gbviForce, std::vector<Vec3>& positions) {
const int numParticles = 8;
double C_HBondDistance = 0.1097;
double C_CBondDistance = 0.1504;
double C_radius, C_gamma, C_charge, H_radius, H_gamma, H_charge;
int AM1_BCC = 1;
H_charge = -0.053;
C_charge = -3.0*H_charge;
if (AM1_BCC) {
C_radius = 0.180;
C_gamma = -0.2863;
H_radius = 0.125;
H_gamma = 0.2437;
}
else {
C_radius = 0.215;
C_gamma = -1.1087;
H_radius = 0.150;
H_gamma = 0.1237;
}
for (int i = 0; i < numParticles; i++) {
gbviForce->addParticle(H_charge, H_radius, H_gamma);
}
gbviForce->setParticleParameters(1, C_charge, C_radius, C_gamma);
gbviForce->setParticleParameters(4, C_charge, C_radius, C_gamma);
gbviForce->addBond(0, 1, C_HBondDistance);
gbviForce->addBond(2, 1, C_HBondDistance);
gbviForce->addBond(3, 1, C_HBondDistance);
gbviForce->addBond(1, 4, C_CBondDistance);
gbviForce->addBond(5, 4, C_HBondDistance);
gbviForce->addBond(6, 4, C_HBondDistance);
gbviForce->addBond(7, 4, C_HBondDistance);
std::vector<pair<int, int> > bondExceptions;
std::vector<double> bondDistances;
bondExceptions.push_back(pair<int, int>(0, 1));
bondDistances.push_back(C_HBondDistance);
bondExceptions.push_back(pair<int, int>(2, 1));
bondDistances.push_back(C_HBondDistance);
bondExceptions.push_back(pair<int, int>(3, 1));
bondDistances.push_back(C_HBondDistance);
bondExceptions.push_back(pair<int, int>(1, 4));
bondDistances.push_back(C_CBondDistance);
bondExceptions.push_back(pair<int, int>(5, 4));
bondDistances.push_back(C_HBondDistance);
bondExceptions.push_back(pair<int, int>(6, 4));
bondDistances.push_back(C_HBondDistance);
bondExceptions.push_back(pair<int, int>(7, 4));
bondDistances.push_back(C_HBondDistance);
positions.resize(numParticles);
positions[0] = Vec3(0.5480, 1.7661, 0.0000);
positions[1] = Vec3(0.7286, 0.8978, 0.6468);
positions[2] = Vec3(0.4974, 0.0000, 0.0588);
positions[3] = Vec3(0.0000, 0.9459, 1.4666);
positions[4] = Vec3(2.1421, 0.8746, 1.1615);
positions[5] = Vec3(2.3239, 0.0050, 1.8065);
positions[6] = Vec3(2.8705, 0.8295, 0.3416);
positions[7] = Vec3(2.3722, 1.7711, 1.7518);
}
// dimer GB/VI test case
static void buildDimer(GBVIForce* gbviForce, std::vector<Vec3>& positions) {
const int numParticles = 2;
double C_HBondDistance = 0.1097;
double C_CBondDistance = 0.1504;
double C_radius, C_gamma, C_charge, H_radius, H_gamma, H_charge;
int AM1_BCC = 1;
H_charge = -0.053;
C_charge = -3.0*H_charge;
H_charge = 0.0;
C_charge = 0.0;
if (AM1_BCC) {
C_radius = 0.180;
C_gamma = -0.2863;
H_radius = 0.125;
H_gamma = 0.2437;
}
else {
C_radius = 0.215;
C_gamma = -1.1087;
H_radius = 0.150;
H_gamma = 0.1237;
}
for (int i = 0; i < numParticles; i++) {
gbviForce->addParticle(H_charge, H_radius, H_gamma);
}
gbviForce->setParticleParameters(1, C_charge, C_radius, C_gamma);
gbviForce->addBond(0, 1, C_HBondDistance);
std::vector<pair<int, int> > bondExceptions;
std::vector<double> bondDistances;
bondExceptions.push_back(pair<int, int>(0, 1));
bondDistances.push_back(C_HBondDistance);
#include "ReferenceTests.h"
#include "TestCustomGBForce.h"
positions.resize(numParticles);
positions[0] = Vec3(0.0, 0.0, 0.0);
positions[1] = Vec3(0.15, 0.0, 0.0);
void runPlatformTests() {
}
// monomer GB/VI test case
static void buildMonomer(GBVIForce* gbviForce, std::vector<Vec3>& positions) {
const int numParticles = 1;
double H_radius, H_gamma, H_charge;
H_charge = 1.0;
H_radius = 0.125;
H_gamma = 0.2437;
for (int i = 0; i < numParticles; i++) {
gbviForce->addParticle(H_charge, H_radius, H_gamma);
}
positions.resize(numParticles);
positions[0] = Vec3(0.0, 0.0, 0.0);
}
// taken from gbviForceImpl class
// computes the scaled radii based on covalent info and atomic radii
static void findScaledRadii(GBVIForce& gbviForce, std::vector<double> & scaledRadii) {
int numberOfParticles = gbviForce.getNumParticles();
int numberOfBonds = gbviForce.getNumBonds();
// load 1-2 atom pairs along w/ bond distance using HarmonicBondForce & constraints
// numberOfBonds < 1, indicating they were not set by the user
std::vector< std::vector<int> > bondIndices;
bondIndices.resize(numberOfBonds);
std::vector<double> bondLengths;
bondLengths.resize(numberOfBonds);
scaledRadii.resize(numberOfParticles);
for (int i = 0; i < numberOfParticles; i++) {
double charge, radius, gamma;
gbviForce.getParticleParameters(i, charge, radius, gamma);
scaledRadii[i] = radius;
}
for (int i = 0; i < numberOfBonds; i++) {
int particle1, particle2;
double bondLength;
gbviForce.getBondParameters(i, particle1, particle2, bondLength);
if (particle1 < 0 || particle1 >= gbviForce.getNumParticles()) {
std::stringstream msg;
msg << "GBVISoftcoreForce: Illegal particle index: ";
msg << particle1;
throw OpenMMException(msg.str());
}
if (particle2 < 0 || particle2 >= gbviForce.getNumParticles()) {
std::stringstream msg;
msg << "GBVISoftcoreForce: Illegal particle index: ";
msg << particle2;
throw OpenMMException(msg.str());
}
if (bondLength < 0) {
std::stringstream msg;
msg << "GBVISoftcoreForce: negative bondlength: ";
msg << bondLength;
throw OpenMMException(msg.str());
}
bondIndices[i].push_back(particle1);
bondIndices[i].push_back(particle2);
bondLengths[i] = bondLength;
}
// load 1-2 indicies for each atom
std::vector<std::vector<int> > bonded12(numberOfParticles);
for (int i = 0; i < (int) bondIndices.size(); ++i) {
bonded12[bondIndices[i][0]].push_back(i);
bonded12[bondIndices[i][1]].push_back(i);
}
int errors = 0;
// compute scaled radii (Eq. 5 of Labute paper [JCC 29 p. 1693-1698 2008])
for (int j = 0; j < (int) bonded12.size(); ++j) {
double charge;
double gamma;
double radiusJ;
double scaledRadiusJ;
gbviForce.getParticleParameters(j, charge, radiusJ, gamma);
if ( bonded12[j].size() == 0) {
scaledRadiusJ = radiusJ;
// errors++;
}
else {
double rJ2 = radiusJ*radiusJ;
// loop over bonded neighbors of atom j, applying Eq. 5 in Labute
scaledRadiusJ = 0.0;
for (int i = 0; i < (int) bonded12[j].size(); ++i) {
int index = bonded12[j][i];
int bondedAtomIndex = (j == bondIndices[index][0]) ? bondIndices[index][1] : bondIndices[index][0];
double radiusI;
gbviForce.getParticleParameters(bondedAtomIndex, charge, radiusI, gamma);
double rI2 = radiusI*radiusI;
double a_ij = (radiusI - bondLengths[index]);
a_ij *= a_ij;
a_ij = (rJ2 - a_ij)/(2.0*bondLengths[index]);
double a_ji = radiusJ - bondLengths[index];
a_ji *= a_ji;
a_ji = (rI2 - a_ji)/(2.0*bondLengths[index]);
scaledRadiusJ += a_ij*a_ij*(3.0*radiusI - a_ij) + a_ji*a_ji*(3.0*radiusJ - a_ji);
}
scaledRadiusJ = (radiusJ*radiusJ*radiusJ) - 0.125*scaledRadiusJ;
if (scaledRadiusJ > 0.0) {
scaledRadiusJ = 0.95*pow(scaledRadiusJ, (1.0/3.0));
}
else {
scaledRadiusJ = 0.0;
}
}
scaledRadii[j] = scaledRadiusJ;
}
// abort if errors
if (errors) {
throw OpenMMException("GBVIForceImpl::findScaledRadii errors -- aborting");
}
}
// load parameters from gbviForce to customGbviForce
// findScaledRadii() is called to calculate the scaled radii (S)
// S is derived quantity in GBVIForce, not a parameter is the case here
static void loadGbviParameters(GBVIForce* gbviForce, CustomGBForce* customGbviForce) {
int numParticles = gbviForce->getNumParticles();
// charge, radius, scale factor, gamma
vector<double> params(4);
std::vector<double> scaledRadii;
findScaledRadii(*gbviForce, scaledRadii);
for (int ii = 0; ii < numParticles; ii++) {
double charge, radius, gamma;
gbviForce->getParticleParameters(ii, charge, radius, gamma);
params[0] = charge;
params[1] = radius;
params[2] = scaledRadii[ii];
params[3] = gamma;
customGbviForce->addParticle(params);
}
}
void testGBVI(GBVIForce::NonbondedMethod gbviMethod, CustomGBForce::NonbondedMethod customGbviMethod, std::string molecule) {
const int numMolecules = 1;
const double boxSize = 10.0;
GBVIForce* gbvi = new GBVIForce();
std::vector<Vec3> positions;
// select molecule
if (molecule == "Monomer") {
buildMonomer(gbvi, positions);
}
else if (molecule == "Dimer") {
buildDimer(gbvi, positions);
}
else {
buildEthane(gbvi, positions);
}
int numParticles = gbvi->getNumParticles();
System standardSystem;
System customGbviSystem;
for (int i = 0; i < numParticles; i++) {
standardSystem.addParticle(1.0);
customGbviSystem.addParticle(1.0);
}
standardSystem.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0.0, 0.0), Vec3(0.0, boxSize, 0.0), Vec3(0.0, 0.0, boxSize));
customGbviSystem.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0.0, 0.0), Vec3(0.0, boxSize, 0.0), Vec3(0.0, 0.0, boxSize));
gbvi->setCutoffDistance(2.0);
// create customGbviForce GBVI force
CustomGBForce* customGbviForce = createCustomGBVI(gbvi->getSolventDielectric(), gbvi->getSoluteDielectric());
customGbviForce->setCutoffDistance(2.0);
// load parameters from gbvi to customGbviForce
loadGbviParameters(gbvi, customGbviForce);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
vector<Vec3> velocities(numParticles);
for (int ii = 0; ii < numParticles; ii++) {
velocities[ii] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt));
}
gbvi->setNonbondedMethod(gbviMethod);
customGbviForce->setNonbondedMethod(customGbviMethod);
standardSystem.addForce(gbvi);
customGbviSystem.addForce(customGbviForce);
VerletIntegrator integrator1(0.01);
VerletIntegrator integrator2(0.01);
Context context1(standardSystem, integrator1, platform);
context1.setPositions(positions);
context1.setVelocities(velocities);
State state1 = context1.getState(State::Forces | State::Energy);
Context context2(customGbviSystem, integrator2, platform);
context2.setPositions(positions);
context2.setVelocities(velocities);
State state2 = context2.getState(State::Forces | State::Energy);
ASSERT_EQUAL_TOL(state1.getPotentialEnergy(), state2.getPotentialEnergy(), 1e-4);
for (int i = 0; i < numParticles; i++) {
ASSERT_EQUAL_VEC(state1.getForces()[i], state2.getForces()[i], 1e-4);
}
}
int main() {
try {
testOBC(GBSAOBCForce::NoCutoff, CustomGBForce::NoCutoff);
testOBC(GBSAOBCForce::CutoffNonPeriodic, CustomGBForce::CutoffNonPeriodic);
testOBC(GBSAOBCForce::CutoffPeriodic, CustomGBForce::CutoffPeriodic);
testMembrane();
testTabulatedFunction();
testMultipleChainRules();
testPositionDependence();
testExclusions();
// GBVI tests
testGBVI(GBVIForce::NoCutoff, CustomGBForce::NoCutoff, "Monomer");
testGBVI(GBVIForce::NoCutoff, CustomGBForce::NoCutoff, "Dimer");
testGBVI(GBVIForce::NoCutoff, CustomGBForce::NoCutoff, "Ethane");
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
}
platforms/reference/tests/TestReferenceCustomHbondForce.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2008-2012 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,221 +29,8 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of CustomHbondForce.
*/
#include "ReferenceTests.h"
#include "TestCustomHbondForce.h"
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/CustomHbondForce.h"
#include "openmm/HarmonicAngleForce.h"
#include "openmm/HarmonicBondForce.h"
#include "openmm/PeriodicTorsionForce.h"
#include "openmm/System.h"
#include "openmm/VerletIntegrator.h"
#include "sfmt/SFMT.h"
#include <iostream>
#include <vector>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
void testHbond() {
// Create a system using a CustomHbondForce.
System customSystem;
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
customSystem.addParticle(1.0);
CustomHbondForce* custom = new CustomHbondForce("0.5*kr*(distance(d1,a1)-r0)^2 + 0.5*ktheta*(angle(a1,d1,d2)-theta0)^2 + 0.5*kpsi*(angle(d1,a1,a2)-psi0)^2 + kchi*(1+cos(n*dihedral(a3,a2,a1,d1)-chi0))");
custom->addPerDonorParameter("r0");
custom->addPerDonorParameter("theta0");
custom->addPerDonorParameter("psi0");
custom->addPerAcceptorParameter("chi0");
custom->addPerAcceptorParameter("n");
custom->addGlobalParameter("kr", 0.4);
custom->addGlobalParameter("ktheta", 0.5);
custom->addGlobalParameter("kpsi", 0.6);
custom->addGlobalParameter("kchi", 0.7);
vector<double> parameters(3);
parameters[0] = 1.5;
parameters[1] = 1.7;
parameters[2] = 1.9;
custom->addDonor(1, 0, -1, parameters);
parameters.resize(2);
parameters[0] = 2.1;
parameters[1] = 2;
custom->addAcceptor(2, 3, 4, parameters);
custom->setCutoffDistance(10.0);
customSystem.addForce(custom);
ASSERT(!custom->usesPeriodicBoundaryConditions());
ASSERT(!customSystem.usesPeriodicBoundaryConditions());
// Create an identical system using HarmonicBondForce, HarmonicAngleForce, and PeriodicTorsionForce.
System standardSystem;
standardSystem.addParticle(1.0);
standardSystem.addParticle(1.0);
standardSystem.addParticle(1.0);
standardSystem.addParticle(1.0);
standardSystem.addParticle(1.0);
HarmonicBondForce* bond = new HarmonicBondForce();
bond->addBond(1, 2, 1.5, 0.4);
standardSystem.addForce(bond);
HarmonicAngleForce* angle = new HarmonicAngleForce();
angle->addAngle(0, 1, 2, 1.7, 0.5);
angle->addAngle(1, 2, 3, 1.9, 0.6);
standardSystem.addForce(angle);
PeriodicTorsionForce* torsion = new PeriodicTorsionForce();
torsion->addTorsion(1, 2, 3, 4, 2, 2.1, 0.7);
standardSystem.addForce(torsion);
// Set the atoms in various positions, and verify that both systems give identical forces and energy.
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
vector<Vec3> positions(5);
VerletIntegrator integrator1(0.01);
VerletIntegrator integrator2(0.01);
Context c1(customSystem, integrator1, platform);
Context c2(standardSystem, integrator2, platform);
for (int i = 0; i < 10; i++) {
for (int j = 0; j < (int) positions.size(); j++)
positions[j] = Vec3(2.0*genrand_real2(sfmt), 2.0*genrand_real2(sfmt), 2.0*genrand_real2(sfmt));
c1.setPositions(positions);
c2.setPositions(positions);
State s1 = c1.getState(State::Forces | State::Energy);
State s2 = c2.getState(State::Forces | State::Energy);
for (int i = 0; i < customSystem.getNumParticles(); i++)
ASSERT_EQUAL_VEC(s2.getForces()[i], s1.getForces()[i], TOL);
ASSERT_EQUAL_TOL(s2.getPotentialEnergy(), s1.getPotentialEnergy(), TOL);
}
// Try changing the parameters and make sure it's still correct.
parameters.resize(3);
parameters[0] = 1.4;
parameters[1] = 1.7;
parameters[2] = 1.9;
custom->setDonorParameters(0, 1, 0, -1, parameters);
parameters.resize(2);
parameters[0] = 2.2;
parameters[1] = 2;
custom->setAcceptorParameters(0, 2, 3, 4, parameters);
bond->setBondParameters(0, 1, 2, 1.4, 0.4);
torsion->setTorsionParameters(0, 1, 2, 3, 4, 2, 2.2, 0.7);
custom->updateParametersInContext(c1);
bond->updateParametersInContext(c2);
torsion->updateParametersInContext(c2);
State s1 = c1.getState(State::Forces | State::Energy);
State s2 = c2.getState(State::Forces | State::Energy);
for (int i = 0; i < customSystem.getNumParticles(); i++)
ASSERT_EQUAL_VEC(s2.getForces()[i], s1.getForces()[i], TOL);
ASSERT_EQUAL_TOL(s2.getPotentialEnergy(), s1.getPotentialEnergy(), TOL);
}
void testExclusions() {
System system;
system.addParticle(1.0);
system.addParticle(1.0);
system.addParticle(1.0);
VerletIntegrator integrator(0.01);
CustomHbondForce* custom = new CustomHbondForce("(distance(d1,a1)-1)^2");
custom->addDonor(0, 1, -1, vector<double>());
custom->addDonor(1, 0, -1, vector<double>());
custom->addAcceptor(2, 0, -1, vector<double>());
custom->addExclusion(1, 0);
system.addForce(custom);
Context context(system, integrator, platform);
vector<Vec3> positions(3);
positions[0] = Vec3(0, 0, 0);
positions[1] = Vec3(0, 2, 0);
positions[2] = Vec3(2, 0, 0);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = state.getForces();
ASSERT_EQUAL_VEC(Vec3(2, 0, 0), forces[0], TOL);
ASSERT_EQUAL_VEC(Vec3(0, 0, 0), forces[1], TOL);
ASSERT_EQUAL_VEC(Vec3(-2, 0, 0), forces[2], TOL);
ASSERT_EQUAL_TOL(1.0, state.getPotentialEnergy(), TOL);
}
void testCutoff() {
System system;
system.addParticle(1.0);
system.addParticle(1.0);
system.addParticle(1.0);
VerletIntegrator integrator(0.01);
CustomHbondForce* custom = new CustomHbondForce("(distance(d1,a1)-1)^2");
custom->addDonor(0, 1, -1, vector<double>());
custom->addDonor(1, 0, -1, vector<double>());
custom->addAcceptor(2, 0, -1, vector<double>());
custom->setNonbondedMethod(CustomHbondForce::CutoffNonPeriodic);
custom->setCutoffDistance(2.5);
system.addForce(custom);
Context context(system, integrator, platform);
vector<Vec3> positions(3);
positions[0] = Vec3(0, 0, 0);
positions[1] = Vec3(0, 3, 0);
positions[2] = Vec3(2, 0, 0);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = state.getForces();
ASSERT_EQUAL_VEC(Vec3(2, 0, 0), forces[0], TOL);
ASSERT_EQUAL_VEC(Vec3(0, 0, 0), forces[1], TOL);
ASSERT_EQUAL_VEC(Vec3(-2, 0, 0), forces[2], TOL);
ASSERT_EQUAL_TOL(1.0, state.getPotentialEnergy(), TOL);
void runPlatformTests() {
}
void testCustomFunctions() {
System system;
system.addParticle(1.0);
system.addParticle(1.0);
system.addParticle(1.0);
VerletIntegrator integrator(0.01);
CustomHbondForce* custom = new CustomHbondForce("foo(distance(d1,a1))");
custom->addDonor(1, 0, -1, vector<double>());
custom->addDonor(2, 0, -1, vector<double>());
custom->addAcceptor(0, 1, -1, vector<double>());
vector<double> function(2);
function[0] = 0;
function[1] = 1;
custom->addTabulatedFunction("foo", new Continuous1DFunction(function, 0, 10));
system.addForce(custom);
Context context(system, integrator, platform);
vector<Vec3> positions(3);
positions[0] = Vec3(0, 0, 0);
positions[1] = Vec3(0, 2, 0);
positions[2] = Vec3(2, 0, 0);
context.setPositions(positions);
State state = context.getState(State::Forces | State::Energy);
const vector<Vec3>& forces = state.getForces();
ASSERT_EQUAL_VEC(Vec3(0.1, 0.1, 0), forces[0], TOL);
ASSERT_EQUAL_VEC(Vec3(0, -0.1, 0), forces[1], TOL);
ASSERT_EQUAL_VEC(Vec3(-0.1, 0, 0), forces[2], TOL);
ASSERT_EQUAL_TOL(0.1*2+0.1*2, state.getPotentialEnergy(), TOL);
}
int main() {
try {
testHbond();
testExclusions();
testCutoff();
testCustomFunctions();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
}
platforms/reference/tests/TestReferenceCustomIntegrator.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2008-2015 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,747 +29,8 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of CustomIntegrator.
*/
#include "ReferenceTests.h"
#include "TestCustomIntegrator.h"
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/AndersenThermostat.h"
#include "openmm/HarmonicBondForce.h"
#include "openmm/NonbondedForce.h"
#include "openmm/System.h"
#include "openmm/CustomIntegrator.h"
#include "SimTKOpenMMRealType.h"
#include "sfmt/SFMT.h"
#include <iostream>
#include <vector>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
/**
* Test a simple leapfrog integrator on a single bond.
*/
void testSingleBond() {
System system;
system.addParticle(2.0);
system.addParticle(2.0);
const double dt = 0.01;
CustomIntegrator integrator(dt);
integrator.addComputePerDof("v", "v+dt*f/m");
integrator.addComputePerDof("x", "x+dt*v");
integrator.setKineticEnergyExpression("m*v1*v1/2; v1=v+0.5*dt*f/m");
HarmonicBondForce* forceField = new HarmonicBondForce();
forceField->addBond(0, 1, 1.5, 1);
system.addForce(forceField);
Context context(system, integrator, platform);
vector<Vec3> positions(2);
positions[0] = Vec3(-1, 0, 0);
positions[1] = Vec3(1, 0, 0);
context.setPositions(positions);
vector<Vec3> velocities(2);
velocities[0] = Vec3(-0.5*dt*0.5*0.5, 0, 0);
velocities[1] = Vec3(0.5*dt*0.5*0.5, 0, 0);
context.setVelocities(velocities);
// This is simply a harmonic oscillator, so compare it to the analytical solution.
const double freq = 1.0;;
for (int i = 0; i < 1000; ++i) {
State state = context.getState(State::Positions | State::Velocities | State::Energy);
double time = state.getTime();
double expectedDist = 1.5+0.5*std::cos(freq*time);
ASSERT_EQUAL_VEC(Vec3(-0.5*expectedDist, 0, 0), state.getPositions()[0], 1e-4);
ASSERT_EQUAL_VEC(Vec3(0.5*expectedDist, 0, 0), state.getPositions()[1], 1e-4);
double expectedSpeed = -0.5*freq*std::sin(freq*(time-dt/2));
ASSERT_EQUAL_VEC(Vec3(-0.5*expectedSpeed, 0, 0), state.getVelocities()[0], 1e-4);
ASSERT_EQUAL_VEC(Vec3(0.5*expectedSpeed, 0, 0), state.getVelocities()[1], 1e-4);
double energy = state.getKineticEnergy()+state.getPotentialEnergy();
ASSERT_EQUAL_TOL(0.5*0.5*0.5, energy, 1e-4);
integrator.step(1);
}
}
/**
* Test an integrator that enforces constraints.
*/
void testConstraints() {
const int numParticles = 8;
const double temp = 500.0;
System system;
CustomIntegrator integrator(0.002);
integrator.addPerDofVariable("oldx", 0);
integrator.addComputePerDof("v", "v+dt*f/m");
integrator.addComputePerDof("oldx", "x");
integrator.addComputePerDof("x", "x+dt*v");
integrator.addConstrainPositions();
integrator.addComputePerDof("v", "(x-oldx)/dt");
integrator.setConstraintTolerance(1e-5);
NonbondedForce* forceField = new NonbondedForce();
for (int i = 0; i < numParticles; ++i) {
system.addParticle(i%2 == 0 ? 5.0 : 10.0);
forceField->addParticle((i%2 == 0 ? 0.2 : -0.2), 0.5, 5.0);
}
for (int i = 0; i < numParticles-1; ++i)
system.addConstraint(i, i+1, 1.0);
system.addForce(forceField);
Context context(system, integrator, platform);
vector<Vec3> positions(numParticles);
vector<Vec3> velocities(numParticles);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
for (int i = 0; i < numParticles; ++i) {
positions[i] = Vec3(i/2, (i+1)/2, 0);
velocities[i] = Vec3(genrand_real2(sfmt)-0.5, genrand_real2(sfmt)-0.5, genrand_real2(sfmt)-0.5);
}
context.setPositions(positions);
context.setVelocities(velocities);
// Simulate it and see whether the constraints remain satisfied.
double initialEnergy = 0.0;
for (int i = 0; i < 1000; ++i) {
State state = context.getState(State::Positions | State::Energy);
for (int j = 0; j < system.getNumConstraints(); ++j) {
int particle1, particle2;
double distance;
system.getConstraintParameters(j, particle1, particle2, distance);
Vec3 p1 = state.getPositions()[particle1];
Vec3 p2 = state.getPositions()[particle2];
double dist = std::sqrt((p1[0]-p2[0])*(p1[0]-p2[0])+(p1[1]-p2[1])*(p1[1]-p2[1])+(p1[2]-p2[2])*(p1[2]-p2[2]));
ASSERT_EQUAL_TOL(distance, dist, 2e-5);
}
double energy = state.getKineticEnergy()+state.getPotentialEnergy();
if (i == 1)
initialEnergy = energy;
else if (i > 1)
ASSERT_EQUAL_TOL(initialEnergy, energy, 0.01);
integrator.step(1);
}
}
/**
* Test an integrator that applies constraints directly to velocities.
*/
void testVelocityConstraints() {
const int numParticles = 10;
System system;
CustomIntegrator integrator(0.002);
integrator.addPerDofVariable("x1", 0);
integrator.addComputePerDof("v", "v+0.5*dt*f/m");
integrator.addComputePerDof("x", "x+dt*v");
integrator.addComputePerDof("x1", "x");
integrator.addConstrainPositions();
integrator.addComputePerDof("v", "v+0.5*dt*f/m+(x-x1)/dt");
integrator.addConstrainVelocities();
integrator.setConstraintTolerance(1e-5);
NonbondedForce* forceField = new NonbondedForce();
for (int i = 0; i < numParticles; ++i) {
system.addParticle(i%2 == 0 ? 5.0 : 10.0);
forceField->addParticle((i%2 == 0 ? 0.2 : -0.2), 0.5, 5.0);
}
// Constrain the first three particles with SHAKE.
system.addConstraint(0, 1, 1.0);
system.addConstraint(1, 2, 1.0);
// Constrain the next three with SETTLE.
system.addConstraint(3, 4, 1.0);
system.addConstraint(5, 4, 1.0);
system.addConstraint(3, 5, sqrt(2.0));
// Constraint the rest with CCMA.
for (int i = 6; i < numParticles-1; ++i)
system.addConstraint(i, i+1, 1.0);
system.addForce(forceField);
Context context(system, integrator, platform);
vector<Vec3> positions(numParticles);
vector<Vec3> velocities(numParticles);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
for (int i = 0; i < numParticles; ++i) {
positions[i] = Vec3(i/2, (i+1)/2, 0);
velocities[i] = Vec3(genrand_real2(sfmt)-0.5, genrand_real2(sfmt)-0.5, genrand_real2(sfmt)-0.5);
}
context.setPositions(positions);
context.setVelocities(velocities);
// Simulate it and see whether the constraints remain satisfied.
double initialEnergy = 0.0;
for (int i = 0; i < 1000; ++i) {
integrator.step(2);
State state = context.getState(State::Positions | State::Velocities | State::Energy);
for (int j = 0; j < system.getNumConstraints(); ++j) {
int particle1, particle2;
double distance;
system.getConstraintParameters(j, particle1, particle2, distance);
Vec3 p1 = state.getPositions()[particle1];
Vec3 p2 = state.getPositions()[particle2];
double dist = std::sqrt((p1[0]-p2[0])*(p1[0]-p2[0])+(p1[1]-p2[1])*(p1[1]-p2[1])+(p1[2]-p2[2])*(p1[2]-p2[2]));
ASSERT_EQUAL_TOL(distance, dist, 2e-5);
if (i > 0) {
Vec3 v1 = state.getVelocities()[particle1];
Vec3 v2 = state.getVelocities()[particle2];
double vel = (v1-v2).dot(p1-p2);
ASSERT_EQUAL_TOL(0.0, vel, 2e-5);
}
}
double energy = state.getKineticEnergy()+state.getPotentialEnergy();
if (i == 0)
initialEnergy = energy;
else if (i > 0)
ASSERT_EQUAL_TOL(initialEnergy, energy, 0.01);
}
}
void testConstrainedMasslessParticles() {
System system;
system.addParticle(0.0);
system.addParticle(1.0);
system.addConstraint(0, 1, 1.5);
vector<Vec3> positions(2);
positions[0] = Vec3(-1, 0, 0);
positions[1] = Vec3(1, 0, 0);
CustomIntegrator integrator(0.002);
integrator.addPerDofVariable("oldx", 0);
integrator.addComputePerDof("v", "v+dt*f/m");
integrator.addComputePerDof("oldx", "x");
integrator.addComputePerDof("x", "x+dt*v");
integrator.addConstrainPositions();
integrator.addComputePerDof("v", "(x-oldx)/dt");
bool failed = false;
try {
// This should throw an exception.
Context context(system, integrator, platform);
}
catch (exception& ex) {
failed = true;
}
ASSERT(failed);
// Now make both particles massless, which should work.
system.setParticleMass(1, 0.0);
Context context(system, integrator, platform);
context.setPositions(positions);
context.setVelocitiesToTemperature(300.0);
integrator.step(1);
State state = context.getState(State::Velocities | State::Positions);
ASSERT_EQUAL(0.0, state.getVelocities()[0][0]);
}
/**
* Test an integrator with an AndersenThermostat to see if updateContextState()
* is being handled correctly.
*/
void testWithThermostat() {
const int numParticles = 8;
const double temp = 100.0;
const double collisionFreq = 10.0;
const int numSteps = 5000;
System system;
CustomIntegrator integrator(0.003);
integrator.addUpdateContextState();
integrator.addComputePerDof("v", "v+dt*f/m");
integrator.addComputePerDof("x", "x+dt*v");
NonbondedForce* forceField = new NonbondedForce();
for (int i = 0; i < numParticles; ++i) {
system.addParticle(2.0);
forceField->addParticle((i%2 == 0 ? 1.0 : -1.0), 1.0, 5.0);
}
system.addForce(forceField);
AndersenThermostat* thermostat = new AndersenThermostat(temp, collisionFreq);
system.addForce(thermostat);
Context context(system, integrator, platform);
vector<Vec3> positions(numParticles);
for (int i = 0; i < numParticles; ++i)
positions[i] = Vec3((i%2 == 0 ? 2 : -2), (i%4 < 2 ? 2 : -2), (i < 4 ? 2 : -2));
context.setPositions(positions);
context.setVelocitiesToTemperature(temp);
// Let it equilibrate.
integrator.step(10000);
// Now run it for a while and see if the temperature is correct.
double ke = 0.0;
for (int i = 0; i < numSteps; ++i) {
State state = context.getState(State::Energy);
ke += state.getKineticEnergy();
integrator.step(10);
}
ke /= numSteps;
double expected = 0.5*numParticles*3*BOLTZ*temp;
ASSERT_USUALLY_EQUAL_TOL(expected, ke, 0.1);
}
/**
* Test a Monte Carlo integrator that uses global variables and depends on energy.
*/
void testMonteCarlo() {
System system;
system.addParticle(1.0);
system.addParticle(1.0);
CustomIntegrator integrator(0.1);
const double kT = BOLTZ*300.0;
integrator.addGlobalVariable("kT", kT);
integrator.addGlobalVariable("oldE", 0);
integrator.addGlobalVariable("accept", 0);
integrator.addPerDofVariable("oldx", 0);
integrator.addComputeGlobal("oldE", "energy");
integrator.addComputePerDof("oldx", "x");
integrator.addComputePerDof("x", "x+dt*gaussian");
integrator.addComputeGlobal("accept", "step(exp((oldE-energy)/kT)-uniform)");
integrator.addComputePerDof("x", "select(accept, x, oldx)");
HarmonicBondForce* forceField = new HarmonicBondForce();
forceField->addBond(0, 1, 2.0, 10.0);
system.addForce(forceField);
Context context(system, integrator, platform);
vector<Vec3> positions(2);
positions[0] = Vec3(-1, 0, 0);
positions[1] = Vec3(1, 0, 0);
context.setPositions(positions);
// Compute the histogram of distances and see if it satisfies a Boltzmann distribution.
const int numBins = 100;
const double maxDist = 4.0;
const int numIterations = 5000;
vector<int> counts(numBins, 0);
for (int i = 0; i < numIterations; ++i) {
integrator.step(10);
State state = context.getState(State::Positions);
Vec3 delta = state.getPositions()[0]-state.getPositions()[1];
double dist = sqrt(delta.dot(delta));
if (dist < maxDist)
counts[(int) (numBins*dist/maxDist)]++;
}
vector<double> expected(numBins, 0);
double sum = 0;
for (int i = 0; i < numBins; i++) {
double dist = (i+0.5)*maxDist/numBins;
expected[i] = dist*dist*exp(-5.0*(dist-2)*(dist-2)/kT);
sum += expected[i];
}
for (int i = 0; i < numBins; i++)
ASSERT_USUALLY_EQUAL_TOL((double) counts[i]/numIterations, expected[i]/sum, 0.01);
}
/**
* Test the ComputeSum operation.
*/
void testSum() {
const int numParticles = 200;
const double boxSize = 10;
System system;
system.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0, 0), Vec3(0, boxSize, 0), Vec3(0, 0, boxSize));
NonbondedForce* nb = new NonbondedForce();
system.addForce(nb);
vector<Vec3> positions(numParticles);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
for (int i = 0; i < numParticles; i++) {
system.addParticle(i%10 == 0 ? 0.0 : 1.5);
nb->addParticle(i%2 == 0 ? 0.1 : -0.1, 0.1, 1);
bool close = true;
while (close) {
positions[i] = Vec3(boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt));
close = false;
for (int j = 0; j < i; ++j) {
Vec3 delta = positions[i]-positions[j];
if (delta.dot(delta) < 1)
close = true;
}
}
}
CustomIntegrator integrator(0.005);
integrator.addGlobalVariable("ke", 0);
integrator.addComputePerDof("v", "v+dt*f/m");
integrator.addComputePerDof("x", "x+dt*v");
integrator.addComputeSum("ke", "m*v*v/2");
Context context(system, integrator, platform);
context.setPositions(positions);
// See if the sum is being computed correctly.
for (int i = 0; i < 100; ++i) {
State state = context.getState(State::Energy);
ASSERT_EQUAL_TOL(state.getKineticEnergy(), integrator.getGlobalVariable(0), 1e-5);
integrator.step(1);
}
}
/**
* Test an integrator that both uses and modifies a context parameter.
*/
void testParameter() {
System system;
system.addParticle(1.0);
AndersenThermostat* thermostat = new AndersenThermostat(0.1, 0.1);
system.addForce(thermostat);
CustomIntegrator integrator(0.1);
integrator.addGlobalVariable("temp", 0);
integrator.addComputeGlobal("temp", "AndersenTemperature");
integrator.addComputeGlobal("AndersenTemperature", "temp*2");
Context context(system, integrator, platform);
// See if the parameter is being used correctly.
for (int i = 0; i < 10; i++) {
integrator.step(1);
ASSERT_EQUAL_TOL(context.getParameter("AndersenTemperature"), 0.1*(1<<(i+1)), 1e-10);
}
}
/**
* Test random number distributions.
*/
void testRandomDistributions() {
const int numParticles = 100;
const int numBins = 20;
const int numSteps = 100;
System system;
for (int i = 0; i < numParticles; i++)
system.addParticle(1.0);
CustomIntegrator integrator(0.1);
integrator.addPerDofVariable("a", 0);
integrator.addPerDofVariable("b", 0);
integrator.addComputePerDof("a", "uniform");
integrator.addComputePerDof("b", "gaussian");
Context context(system, integrator, platform);
// See if the random numbers are distributed correctly.
vector<int> bins(numBins);
double mean = 0.0;
double var = 0.0;
double skew = 0.0;
double kurtosis = 0.0;
vector<Vec3> values;
for (int i = 0; i < numSteps; i++) {
integrator.step(1);
integrator.getPerDofVariable(0, values);
for (int i = 0; i < numParticles; i++)
for (int j = 0; j < 3; j++) {
double v = values[i][j];
ASSERT(v >= 0 && v < 1);
bins[(int) (v*numBins)]++;
}
integrator.getPerDofVariable(1, values);
for (int i = 0; i < numParticles; i++)
for (int j = 0; j < 3; j++) {
double v = values[i][j];
mean += v;
var += v*v;
skew += v*v*v;
kurtosis += v*v*v*v;
}
}
// Check the distribution of uniform randoms.
int numValues = numParticles*numSteps*3;
double expected = numValues/(double) numBins;
double tol = 4*sqrt(expected);
for (int i = 0; i < numBins; i++)
ASSERT(bins[i] >= expected-tol && bins[i] <= expected+tol);
// Check the distribution of gaussian randoms.
mean /= numValues;
var /= numValues;
skew /= numValues;
kurtosis /= numValues;
double c2 = var-mean*mean;
double c3 = skew-3*var*mean+2*mean*mean*mean;
double c4 = kurtosis-4*skew*mean-3*var*var+12*var*mean*mean-6*mean*mean*mean*mean;
ASSERT_EQUAL_TOL(0.0, mean, 3.0/sqrt((double) numValues));
ASSERT_EQUAL_TOL(1.0, c2, 3.0/pow(numValues, 1.0/3.0));
ASSERT_EQUAL_TOL(0.0, c3, 3.0/pow(numValues, 1.0/4.0));
ASSERT_EQUAL_TOL(0.0, c4, 3.0/pow(numValues, 1.0/4.0));
}
/**
* Test getting and setting per-DOF variables.
*/
void testPerDofVariables() {
const int numParticles = 200;
const double boxSize = 10;
System system;
system.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0, 0), Vec3(0, boxSize, 0), Vec3(0, 0, boxSize));
NonbondedForce* nb = new NonbondedForce();
system.addForce(nb);
nb->setNonbondedMethod(NonbondedForce::CutoffNonPeriodic);
vector<Vec3> positions(numParticles);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
for (int i = 0; i < numParticles; i++) {
system.addParticle(1.5);
nb->addParticle(i%2 == 0 ? 1 : -1, 0.1, 1);
bool close = true;
while (close) {
positions[i] = Vec3(boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt));
close = false;
for (int j = 0; j < i; ++j) {
Vec3 delta = positions[i]-positions[j];
if (delta.dot(delta) < 0.1)
close = true;
}
}
}
CustomIntegrator integrator(0.01);
integrator.addPerDofVariable("temp", 0);
integrator.addPerDofVariable("pos", 0);
integrator.addComputePerDof("v", "v+dt*f/m");
integrator.addComputePerDof("x", "x+dt*v");
integrator.addComputePerDof("pos", "x");
Context context(system, integrator, platform);
context.setPositions(positions);
vector<Vec3> initialValues(numParticles);
for (int i = 0; i < numParticles; i++)
initialValues[i] = Vec3(i+0.1, i+0.2, i+0.3);
integrator.setPerDofVariable(0, initialValues);
// Run a simulation, then query per-DOF values and see if they are correct.
vector<Vec3> values;
for (int i = 0; i < 100; ++i) {
integrator.step(1);
State state = context.getState(State::Positions);
integrator.getPerDofVariable(0, values);
for (int j = 0; j < numParticles; j++)
ASSERT_EQUAL_VEC(initialValues[j], values[j], 1e-5);
integrator.getPerDofVariable(1, values);
for (int j = 0; j < numParticles; j++)
ASSERT_EQUAL_VEC(state.getPositions()[j], values[j], 1e-5);
}
}
/**
* Test evaluating force groups separately.
*/
void testForceGroups() {
System system;
system.addParticle(2.0);
system.addParticle(2.0);
CustomIntegrator integrator(0.01);
integrator.addPerDofVariable("outf", 0);
integrator.addPerDofVariable("outf1", 0);
integrator.addPerDofVariable("outf2", 0);
integrator.addGlobalVariable("oute", 0);
integrator.addGlobalVariable("oute1", 0);
integrator.addGlobalVariable("oute2", 0);
integrator.addComputePerDof("outf", "f");
integrator.addComputePerDof("outf1", "f1");
integrator.addComputePerDof("outf2", "f2");
integrator.addComputeGlobal("oute", "energy");
integrator.addComputeGlobal("oute1", "energy1");
integrator.addComputeGlobal("oute2", "energy2");
HarmonicBondForce* bonds = new HarmonicBondForce();
bonds->addBond(0, 1, 1.5, 1.1);
bonds->setForceGroup(1);
system.addForce(bonds);
NonbondedForce* nb = new NonbondedForce();
nb->addParticle(0.2, 1, 0);
nb->addParticle(0.2, 1, 0);
nb->setForceGroup(2);
system.addForce(nb);
Context context(system, integrator, platform);
vector<Vec3> positions(2);
positions[0] = Vec3(-1, 0, 0);
positions[1] = Vec3(1, 0, 0);
context.setPositions(positions);
// See if the various forces are computed correctly.
integrator.step(1);
vector<Vec3> f, f1, f2;
double e1 = 0.5*1.1*0.5*0.5;
double e2 = 138.935456*0.2*0.2/2.0;
integrator.getPerDofVariable(0, f);
integrator.getPerDofVariable(1, f1);
integrator.getPerDofVariable(2, f2);
ASSERT_EQUAL_VEC(Vec3(1.1*0.5, 0, 0), f1[0], 1e-5);
ASSERT_EQUAL_VEC(Vec3(-1.1*0.5, 0, 0), f1[1], 1e-5);
ASSERT_EQUAL_VEC(Vec3(-138.935456*0.2*0.2/4.0, 0, 0), f2[0], 1e-5);
ASSERT_EQUAL_VEC(Vec3(138.935456*0.2*0.2/4.0, 0, 0), f2[1], 1e-5);
ASSERT_EQUAL_VEC(f1[0]+f2[0], f[0], 1e-5);
ASSERT_EQUAL_VEC(f1[1]+f2[1], f[1], 1e-5);
ASSERT_EQUAL_TOL(e1, integrator.getGlobalVariable(1), 1e-5);
ASSERT_EQUAL_TOL(e2, integrator.getGlobalVariable(2), 1e-5);
ASSERT_EQUAL_TOL(e1+e2, integrator.getGlobalVariable(0), 1e-5);
// Make sure they also match the values returned by the Context.
State s = context.getState(State::Forces | State::Energy, false);
State s1 = context.getState(State::Forces | State::Energy, false, 2);
State s2 = context.getState(State::Forces | State::Energy, false, 4);
vector<Vec3> c, c1, c2;
c = context.getState(State::Forces, false).getForces();
c1 = context.getState(State::Forces, false, 2).getForces();
c2 = context.getState(State::Forces, false, 4).getForces();
ASSERT_EQUAL_VEC(f[0], c[0], 1e-5);
ASSERT_EQUAL_VEC(f[1], c[1], 1e-5);
ASSERT_EQUAL_VEC(f1[0], c1[0], 1e-5);
ASSERT_EQUAL_VEC(f1[1], c1[1], 1e-5);
ASSERT_EQUAL_VEC(f2[0], c2[0], 1e-5);
ASSERT_EQUAL_VEC(f2[1], c2[1], 1e-5);
ASSERT_EQUAL_TOL(s.getPotentialEnergy(), integrator.getGlobalVariable(0), 1e-5);
ASSERT_EQUAL_TOL(s1.getPotentialEnergy(), integrator.getGlobalVariable(1), 1e-5);
ASSERT_EQUAL_TOL(s2.getPotentialEnergy(), integrator.getGlobalVariable(2), 1e-5);
}
/**
* Test a multiple time step r-RESPA integrator.
*/
void testRespa() {
const int numParticles = 8;
System system;
system.setDefaultPeriodicBoxVectors(Vec3(4, 0, 0), Vec3(0, 4, 0), Vec3(0, 0, 4));
CustomIntegrator integrator(0.002);
integrator.addComputePerDof("v", "v+0.5*dt*f1/m");
for (int i = 0; i < 2; i++) {
integrator.addComputePerDof("v", "v+0.5*(dt/2)*f0/m");
integrator.addComputePerDof("x", "x+(dt/2)*v");
integrator.addComputePerDof("v", "v+0.5*(dt/2)*f0/m");
}
integrator.addComputePerDof("v", "v+0.5*dt*f1/m");
HarmonicBondForce* bonds = new HarmonicBondForce();
for (int i = 0; i < numParticles-2; i++)
bonds->addBond(i, i+1, 1.0, 0.5);
system.addForce(bonds);
NonbondedForce* nb = new NonbondedForce();
nb->setCutoffDistance(2.0);
nb->setNonbondedMethod(NonbondedForce::Ewald);
for (int i = 0; i < numParticles; ++i) {
system.addParticle(i%2 == 0 ? 5.0 : 10.0);
nb->addParticle((i%2 == 0 ? 0.2 : -0.2), 0.5, 5.0);
}
nb->setForceGroup(1);
nb->setReciprocalSpaceForceGroup(0);
system.addForce(nb);
Context context(system, integrator, platform);
vector<Vec3> positions(numParticles);
vector<Vec3> velocities(numParticles);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
for (int i = 0; i < numParticles; ++i) {
positions[i] = Vec3(i/2, (i+1)/2, 0);
velocities[i] = Vec3(genrand_real2(sfmt)-0.5, genrand_real2(sfmt)-0.5, genrand_real2(sfmt)-0.5);
}
context.setPositions(positions);
context.setVelocities(velocities);
// Simulate it and monitor energy conservations.
double initialEnergy = 0.0;
for (int i = 0; i < 1000; ++i) {
State state = context.getState(State::Energy);
double energy = state.getKineticEnergy()+state.getPotentialEnergy();
if (i == 1)
initialEnergy = energy;
else if (i > 1)
ASSERT_EQUAL_TOL(initialEnergy, energy, 0.05);
integrator.step(2);
}
}
void testIfBlock() {
System system;
system.addParticle(2.0);
system.addParticle(2.0);
const double dt = 0.01;
CustomIntegrator integrator(dt);
integrator.addGlobalVariable("a", 0);
integrator.addGlobalVariable("b", 0);
integrator.addComputeGlobal("b", "1");
integrator.beginIfBlock("a < 3.5");
integrator.addComputeGlobal("b", "a+1");
integrator.endBlock();
Context context(system, integrator, platform);
// Set "a" to 1.7 and verify that "b" gets set to a+1.
integrator.setGlobalVariable(0, 1.7);
integrator.step(1);
ASSERT_EQUAL_TOL(2.7, integrator.getGlobalVariable(1), 1e-6);
// Now set it to a value that should cause the block to be skipped.
integrator.setGlobalVariable(0, 4.1);
integrator.step(1);
ASSERT_EQUAL_TOL(1.0, integrator.getGlobalVariable(1), 1e-6);
}
void testWhileBlock() {
System system;
system.addParticle(2.0);
system.addParticle(2.0);
const double dt = 0.01;
CustomIntegrator integrator(dt);
integrator.addGlobalVariable("a", 0);
integrator.addGlobalVariable("b", 0);
integrator.addComputeGlobal("b", "1");
integrator.beginWhileBlock("b <= a");
integrator.addComputeGlobal("b", "b+1");
integrator.endBlock();
Context context(system, integrator, platform);
// Try a case where the loop should be skipped.
integrator.setGlobalVariable(0, -3.3);
integrator.step(1);
ASSERT_EQUAL_TOL(1.0, integrator.getGlobalVariable(1), 1e-6);
// In this case it should be executed exactly once.
integrator.setGlobalVariable(0, 1.2);
integrator.step(1);
ASSERT_EQUAL_TOL(2.0, integrator.getGlobalVariable(1), 1e-6);
// In this case, it should be executed several times.
integrator.setGlobalVariable(0, 5.3);
integrator.step(1);
ASSERT_EQUAL_TOL(6.0, integrator.getGlobalVariable(1), 1e-6);
}
int main() {
try {
testSingleBond();
testConstraints();
testVelocityConstraints();
testConstrainedMasslessParticles();
testWithThermostat();
testMonteCarlo();
testSum();
testParameter();
testRandomDistributions();
testPerDofVariables();
testForceGroups();
testRespa();
testIfBlock();
testWhileBlock();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
void runPlatformTests() {
}
platforms/reference/tests/TestReferenceCustomManyParticleForce.cpp
View file @ cecc774a
......@@ -6,7 +6,7 @@
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2014 Stanford University and the Authors. *
* Portions copyright (c) 2015 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
......@@ -29,627 +29,8 @@
* USE OR OTHER DEALINGS IN THE SOFTWARE. *
* -------------------------------------------------------------------------- */
/**
* This tests the reference implementation of CustomManyParticleForce.
*/
#include "ReferenceTests.h"
#include "TestCustomManyParticleForce.h"
#ifdef WIN32
#define _USE_MATH_DEFINES // Needed to get M_PI
#endif
#include "openmm/internal/AssertionUtilities.h"
#include "openmm/Context.h"
#include "ReferencePlatform.h"
#include "openmm/CustomCompoundBondForce.h"
#include "openmm/CustomManyParticleForce.h"
#include "openmm/System.h"
#include "openmm/TabulatedFunction.h"
#include "openmm/VerletIntegrator.h"
#include "sfmt/SFMT.h"
#include <iostream>
#include <vector>
using namespace OpenMM;
using namespace std;
ReferencePlatform platform;
const double TOL = 1e-5;
Vec3 computeDelta(const Vec3& pos1, const Vec3& pos2, bool periodic, const Vec3* periodicBoxVectors) {
Vec3 diff = pos1-pos2;
if (periodic) {
diff -= periodicBoxVectors[2]*floor(diff[2]/periodicBoxVectors[2][2]+0.5);
diff -= periodicBoxVectors[1]*floor(diff[1]/periodicBoxVectors[1][1]+0.5);
diff -= periodicBoxVectors[0]*floor(diff[0]/periodicBoxVectors[0][0]+0.5);
}
return diff;
}
void validateAxilrodTeller(CustomManyParticleForce* force, const vector<Vec3>& positions, const vector<const int*>& expectedSets, double boxSize, bool triclinic) {
// Create a System and Context.
int numParticles = force->getNumParticles();
CustomManyParticleForce::NonbondedMethod nonbondedMethod = force->getNonbondedMethod();
System system;
for (int i = 0; i < numParticles; i++)
system.addParticle(1.0);
Vec3 boxVectors[3];
if (triclinic) {
boxVectors[0] = Vec3(boxSize, 0, 0);
boxVectors[1] = Vec3(0.2*boxSize, boxSize, 0);
boxVectors[2] = Vec3(-0.3*boxSize, -0.1*boxSize, boxSize);
}
else {
boxVectors[0] = Vec3(boxSize, 0, 0);
boxVectors[1] = Vec3(0, boxSize, 0);
boxVectors[2] = Vec3(0, 0, boxSize);
}
system.setDefaultPeriodicBoxVectors(boxVectors[0], boxVectors[1], boxVectors[2]);
system.addForce(force);
if (force->getNonbondedMethod() == CustomManyParticleForce::CutoffPeriodic) {
ASSERT(force->usesPeriodicBoundaryConditions());
ASSERT(system.usesPeriodicBoundaryConditions());
}
else {
ASSERT(!force->usesPeriodicBoundaryConditions());
ASSERT(!system.usesPeriodicBoundaryConditions());
}
VerletIntegrator integrator(0.001);
Context context(system, integrator, platform);
context.setPositions(positions);
State state1 = context.getState(State::Forces | State::Energy);
double c = context.getParameter("C");
// See if the energy matches the expected value.
double expectedEnergy = 0;
bool periodic = (nonbondedMethod == CustomManyParticleForce::CutoffPeriodic);
for (int i = 0; i < (int) expectedSets.size(); i++) {
int p1 = expectedSets[i][0];
int p2 = expectedSets[i][1];
int p3 = expectedSets[i][2];
Vec3 d12 = computeDelta(positions[p2], positions[p1], periodic, boxVectors);
Vec3 d13 = computeDelta(positions[p3], positions[p1], periodic, boxVectors);
Vec3 d23 = computeDelta(positions[p3], positions[p2], periodic, boxVectors);
double r12 = sqrt(d12.dot(d12));
double r13 = sqrt(d13.dot(d13));
double r23 = sqrt(d23.dot(d23));
double ctheta1 = d12.dot(d13)/(r12*r13);
double ctheta2 = -d12.dot(d23)/(r12*r23);
double ctheta3 = d13.dot(d23)/(r13*r23);
double rprod = r12*r13*r23;
expectedEnergy += c*(1+3*ctheta1*ctheta2*ctheta3)/(rprod*rprod*rprod);
}
ASSERT_EQUAL_TOL(expectedEnergy, state1.getPotentialEnergy(), 1e-5);
// Take a small step in the direction of the energy gradient and see whether the potential energy changes by the expected amount.
const vector<Vec3>& forces = state1.getForces();
double norm = 0.0;
for (int i = 0; i < (int) forces.size(); ++i)
norm += forces[i].dot(forces[i]);
norm = std::sqrt(norm);
const double stepSize = 1e-3;
double step = 0.5*stepSize/norm;
vector<Vec3> positions2(numParticles), positions3(numParticles);
for (int i = 0; i < (int) positions.size(); ++i) {
Vec3 p = positions[i];
Vec3 f = forces[i];
positions2[i] = Vec3(p[0]-f[0]*step, p[1]-f[1]*step, p[2]-f[2]*step);
positions3[i] = Vec3(p[0]+f[0]*step, p[1]+f[1]*step, p[2]+f[2]*step);
}
context.setPositions(positions2);
State state2 = context.getState(State::Energy);
context.setPositions(positions3);
State state3 = context.getState(State::Energy);
ASSERT_EQUAL_TOL(norm, (state2.getPotentialEnergy()-state3.getPotentialEnergy())/stepSize, 1e-4);
}
void validateStillingerWeber(CustomManyParticleForce* force, const vector<Vec3>& positions, const vector<const int*>& expectedSets, double boxSize) {
// Create a System and Context.
int numParticles = force->getNumParticles();
CustomManyParticleForce::NonbondedMethod nonbondedMethod = force->getNonbondedMethod();
System system;
for (int i = 0; i < numParticles; i++)
system.addParticle(1.0);
system.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0, 0), Vec3(0, boxSize, 0), Vec3(0, 0, boxSize));
system.addForce(force);
VerletIntegrator integrator(0.001);
Context context(system, integrator, platform);
context.setPositions(positions);
State state1 = context.getState(State::Forces | State::Energy);
double L = context.getParameter("L");
double eps = context.getParameter("eps");
double a = context.getParameter("a");
double gamma = context.getParameter("gamma");
double sigma = context.getParameter("sigma");
// See if the energy matches the expected value.
double expectedEnergy = 0;
for (int i = 0; i < (int) expectedSets.size(); i++) {
int p1 = expectedSets[i][0];
int p2 = expectedSets[i][1];
int p3 = expectedSets[i][2];
Vec3 d12 = positions[p2]-positions[p1];
Vec3 d13 = positions[p3]-positions[p1];
Vec3 d23 = positions[p3]-positions[p2];
if (nonbondedMethod == CustomManyParticleForce::CutoffPeriodic) {
for (int j = 0; j < 3; j++) {
d12[j] -= floor(d12[j]/boxSize+0.5f)*boxSize;
d13[j] -= floor(d13[j]/boxSize+0.5f)*boxSize;
d23[j] -= floor(d23[j]/boxSize+0.5f)*boxSize;
}
}
double r12 = sqrt(d12.dot(d12));
double r13 = sqrt(d13.dot(d13));
double r23 = sqrt(d23.dot(d23));
double ctheta1 = d12.dot(d13)/(r12*r13);
double ctheta2 = -d12.dot(d23)/(r12*r23);
double ctheta3 = d13.dot(d23)/(r13*r23);
expectedEnergy += L*eps*(ctheta1+1.0/3.0)*(ctheta1+1.0/3.0)*exp(sigma*gamma/(r12-a*sigma))*exp(sigma*gamma/(r13-a*sigma));
}
ASSERT_EQUAL_TOL(expectedEnergy, state1.getPotentialEnergy(), 1e-5);
// Take a small step in the direction of the energy gradient and see whether the potential energy changes by the expected amount.
const vector<Vec3>& forces = state1.getForces();
double norm = 0.0;
for (int i = 0; i < (int) forces.size(); ++i)
norm += forces[i].dot(forces[i]);
norm = std::sqrt(norm);
const double stepSize = 1e-3;
double step = 0.5*stepSize/norm;
vector<Vec3> positions2(numParticles), positions3(numParticles);
for (int i = 0; i < (int) positions.size(); ++i) {
Vec3 p = positions[i];
Vec3 f = forces[i];
positions2[i] = Vec3(p[0]-f[0]*step, p[1]-f[1]*step, p[2]-f[2]*step);
positions3[i] = Vec3(p[0]+f[0]*step, p[1]+f[1]*step, p[2]+f[2]*step);
}
context.setPositions(positions2);
State state2 = context.getState(State::Energy);
context.setPositions(positions3);
State state3 = context.getState(State::Energy);
ASSERT_EQUAL_TOL(norm, (state2.getPotentialEnergy()-state3.getPotentialEnergy())/stepSize, 1e-4);
}
void testNoCutoff() {
CustomManyParticleForce* force = new CustomManyParticleForce(3,
"C*(1+3*cos(theta1)*cos(theta2)*cos(theta3))/(r12*r13*r23)^3;"
"theta1=angle(p1,p2,p3); theta2=angle(p2,p3,p1); theta3=angle(p3,p1,p2);"
"r12=distance(p1,p2); r13=distance(p1,p3); r23=distance(p2,p3)");
force->addGlobalParameter("C", 1.5);
vector<double> params;
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
vector<Vec3> positions;
positions.push_back(Vec3(0, 0, 0));
positions.push_back(Vec3(1, 0, 0));
positions.push_back(Vec3(0, 1.1, 0.3));
positions.push_back(Vec3(0.4, 0, -0.8));
int sets[4][3] = {{0,1,2}, {1,2,3}, {2,3,0}, {3,0,1}};
vector<const int*> expectedSets(&sets[0], &sets[4]);
validateAxilrodTeller(force, positions, expectedSets, 2.0, false);
}
void testCutoff() {
CustomManyParticleForce* force = new CustomManyParticleForce(3,
"C*(1+3*cos(theta1)*cos(theta2)*cos(theta3))/(r12*r13*r23)^3;"
"theta1=angle(p1,p2,p3); theta2=angle(p2,p3,p1); theta3=angle(p3,p1,p2);"
"r12=distance(p1,p2); r13=distance(p1,p3); r23=distance(p2,p3)");
force->addGlobalParameter("C", 1.5);
force->setNonbondedMethod(CustomManyParticleForce::CutoffNonPeriodic);
force->setCutoffDistance(1.55);
vector<double> params;
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
vector<Vec3> positions;
positions.push_back(Vec3(0, 0, 0));
positions.push_back(Vec3(1, 0, 0));
positions.push_back(Vec3(0, 1.1, 0.3));
positions.push_back(Vec3(0.4, 0, -0.8));
positions.push_back(Vec3(0.2, 0.5, -0.1));
int sets[7][3] = {{0,1,2}, {0,1,3}, {0,1,4}, {0,2,4}, {0,3,4}, {1,2,4}, {1,3,4}};
vector<const int*> expectedSets(&sets[0], &sets[7]);
validateAxilrodTeller(force, positions, expectedSets, 2.0, false);
}
void testPeriodic() {
CustomManyParticleForce* force = new CustomManyParticleForce(3,
"C*(1+3*cos(theta1)*cos(theta2)*cos(theta3))/(r12*r13*r23)^3;"
"theta1=angle(p1,p2,p3); theta2=angle(p2,p3,p1); theta3=angle(p3,p1,p2);"
"r12=distance(p1,p2); r13=distance(p1,p3); r23=distance(p2,p3)");
force->addGlobalParameter("C", 1.5);
force->setNonbondedMethod(CustomManyParticleForce::CutoffPeriodic);
force->setCutoffDistance(1.05);
vector<double> params;
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
vector<Vec3> positions;
positions.push_back(Vec3(0, 0, 0));
positions.push_back(Vec3(1, 0, 0));
positions.push_back(Vec3(0, 1.1, 0.3));
positions.push_back(Vec3(0.4, 0, -0.8));
positions.push_back(Vec3(0.2, 0.5, -0.1));
double boxSize = 2.1;
int sets[5][3] = {{0,1,3}, {0,1,4}, {0,2,4}, {0,3,4}, {1,3,4}};
vector<const int*> expectedSets(&sets[0], &sets[5]);
validateAxilrodTeller(force, positions, expectedSets, boxSize, false);
}
void testTriclinic() {
CustomManyParticleForce* force = new CustomManyParticleForce(3,
"C*(1+3*cos(theta1)*cos(theta2)*cos(theta3))/(r12*r13*r23)^3;"
"theta1=angle(p1,p2,p3); theta2=angle(p2,p3,p1); theta3=angle(p3,p1,p2);"
"r12=distance(p1,p2); r13=distance(p1,p3); r23=distance(p2,p3)");
force->addGlobalParameter("C", 1.5);
force->setNonbondedMethod(CustomManyParticleForce::CutoffPeriodic);
force->setCutoffDistance(1.05);
vector<double> params;
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
vector<Vec3> positions;
positions.push_back(Vec3(0, 0, 0));
positions.push_back(Vec3(1, 0, 0));
positions.push_back(Vec3(0, 1.1, 0.3));
positions.push_back(Vec3(0.4, 0, -0.8));
positions.push_back(Vec3(0.2, 0.5, -0.1));
double boxSize = 2.1;
int sets[4][3] = {{0,1,3}, {0,1,4}, {0,3,4}, {1,3,4}};
vector<const int*> expectedSets(&sets[0], &sets[4]);
validateAxilrodTeller(force, positions, expectedSets, boxSize, true);
}
void testExclusions() {
CustomManyParticleForce* force = new CustomManyParticleForce(3,
"C*(1+3*cos(theta1)*cos(theta2)*cos(theta3))/(r12*r13*r23)^3;"
"theta1=angle(p1,p2,p3); theta2=angle(p2,p3,p1); theta3=angle(p3,p1,p2);"
"r12=distance(p1,p2); r13=distance(p1,p3); r23=distance(p2,p3)");
force->addGlobalParameter("C", 1.5);
vector<double> params;
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
vector<Vec3> positions;
positions.push_back(Vec3(0, 0, 0));
positions.push_back(Vec3(1, 0, 0));
positions.push_back(Vec3(0, 1.1, 0.3));
positions.push_back(Vec3(0.4, 0, -0.8));
positions.push_back(Vec3(0.2, 0.5, -0.1));
force->addExclusion(0, 2);
force->addExclusion(0, 3);
int sets[5][3] = {{0,1,4}, {1,2,3}, {1,2,4}, {1,3,4}, {2,3,4}};
vector<const int*> expectedSets(&sets[0], &sets[5]);
validateAxilrodTeller(force, positions, expectedSets, 2.0, false);
}
void testAllTerms() {
int numParticles = 4;
// Create a system with a CustomManyParticleForce.
System system1;
CustomManyParticleForce* force1 = new CustomManyParticleForce(4,
"distance(p1,p2)+angle(p1,p4,p3)+dihedral(p1,p3,p2,p4)+x1+y4+z3");
system1.addForce(force1);
vector<double> params;
for (int i = 0; i < numParticles; i++) {
system1.addParticle(1.0);
force1->addParticle(params, i);
}
set<int> filter;
filter.insert(0);
force1->setTypeFilter(0, filter);
filter.clear();
filter.insert(1);
force1->setTypeFilter(1, filter);
filter.clear();
filter.insert(3);
force1->setTypeFilter(2, filter);
filter.clear();
filter.insert(2);
force1->setTypeFilter(3, filter);
// Create a system that use a CustomCompoundBondForce to compute exactly the same interactions.
System system2;
CustomCompoundBondForce* force2 = new CustomCompoundBondForce(4,
"distance(p1,p2)+angle(p1,p3,p4)+dihedral(p1,p4,p2,p3)+x1+y3+z4");
system2.addForce(force2);
vector<int> particles;
particles.push_back(0);
particles.push_back(1);
particles.push_back(2);
particles.push_back(3);
force2->addBond(particles, params);
for (int i = 0; i < numParticles; i++)
system2.addParticle(1.0);
// Create contexts for both of them.
vector<Vec3> positions;
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
for (int i = 0; i < numParticles; i++)
positions.push_back(Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt)));
VerletIntegrator integrator1(0.001);
VerletIntegrator integrator2(0.001);
Context context1(system1, integrator1, platform);
Context context2(system2, integrator2, platform);
context1.setPositions(positions);
context2.setPositions(positions);
// See if they produce identical forces and energies.
State state1 = context1.getState(State::Forces | State::Energy);
State state2 = context2.getState(State::Forces | State::Energy);
ASSERT_EQUAL_TOL(state2.getPotentialEnergy(), state1.getPotentialEnergy(), 1e-4);
for (int i = 0; i < numParticles; i++)
ASSERT_EQUAL_VEC(state2.getForces()[i], state1.getForces()[i], 1e-4);
}
void testParameters() {
// Create a system.
int numParticles = 5;
System system;
CustomManyParticleForce* force = new CustomManyParticleForce(3, "C*scale1*scale2*scale3*(distance(p1,p2)+distance(p2,p3)+distance(p1,p3))");
force->addGlobalParameter("C", 2.0);
force->addPerParticleParameter("scale");
vector<double> params(1);
vector<Vec3> positions;
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
for (int i = 0; i < numParticles; i++) {
params[0] = i+1;
force->addParticle(params);
positions.push_back(Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt)));
system.addParticle(1.0);
}
system.addForce(force);
VerletIntegrator integrator(0.001);
Context context(system, integrator, platform);
context.setPositions(positions);
// See if the energy is correct.
State state = context.getState(State::Energy);
double expectedEnergy = 0;
for (int i = 0; i < numParticles; i++)
for (int j = i+1; j < numParticles; j++)
for (int k = j+1; k < numParticles; k++) {
Vec3 d12 = positions[j]-positions[i];
Vec3 d13 = positions[k]-positions[i];
Vec3 d23 = positions[k]-positions[j];
double r12 = sqrt(d12.dot(d12));
double r13 = sqrt(d13.dot(d13));
double r23 = sqrt(d23.dot(d23));
expectedEnergy += 2.0*(i+1)*(j+1)*(k+1)*(r12+r13+r23);
}
ASSERT_EQUAL_TOL(expectedEnergy, state.getPotentialEnergy(), 1e-5);
// Modify the parameters.
context.setParameter("C", 3.5);
for (int i = 0; i < numParticles; i++) {
params[0] = 0.5*i-0.1;
force->setParticleParameters(i, params, 0);
}
force->updateParametersInContext(context);
// See if the energy is still correct.
state = context.getState(State::Energy);
expectedEnergy = 0;
for (int i = 0; i < numParticles; i++)
for (int j = i+1; j < numParticles; j++)
for (int k = j+1; k < numParticles; k++) {
Vec3 d12 = positions[j]-positions[i];
Vec3 d13 = positions[k]-positions[i];
Vec3 d23 = positions[k]-positions[j];
double r12 = sqrt(d12.dot(d12));
double r13 = sqrt(d13.dot(d13));
double r23 = sqrt(d23.dot(d23));
expectedEnergy += 3.5*(0.5*i-0.1)*(0.5*j-0.1)*(0.5*k-0.1)*(r12+r13+r23);
}
ASSERT_EQUAL_TOL(expectedEnergy, state.getPotentialEnergy(), 1e-5);
}
void testTabulatedFunctions() {
int numParticles = 5;
// Create two tabulated functions.
vector<double> values;
values.push_back(0.0);
values.push_back(50.0);
Continuous1DFunction* f1 = new Continuous1DFunction(values, 0, 100);
OpenMM_SFMT::SFMT sfmt;
init_gen_rand(0, sfmt);
vector<double> c(numParticles);
for (int i = 0; i < numParticles; i++)
c[i] = genrand_real2(sfmt);
values.resize(numParticles*numParticles*numParticles);
for (int i = 0; i < numParticles; i++)
for (int j = 0; j < numParticles; j++)
for (int k = 0; k < numParticles; k++)
values[i+numParticles*j+numParticles*numParticles*k] = c[i]+c[j]+c[k];
Discrete3DFunction* f2 = new Discrete3DFunction(numParticles, numParticles, numParticles, values);
// Create a system.
System system;
CustomManyParticleForce* force = new CustomManyParticleForce(3, "f1(distance(p1,p2)+distance(p2,p3)+distance(p1,p3))*f2(atom1, atom2, atom3)");
force->addPerParticleParameter("atom");
force->addTabulatedFunction("f1", f1);
force->addTabulatedFunction("f2", f2);
vector<double> params(1);
vector<Vec3> positions;
for (int i = 0; i < numParticles; i++) {
params[0] = i;
force->addParticle(params);
positions.push_back(Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt)));
system.addParticle(1.0);
}
system.addForce(force);
VerletIntegrator integrator(0.001);
Context context(system, integrator, platform);
context.setPositions(positions);
// See if the energy is correct.
State state = context.getState(State::Energy);
double expectedEnergy = 0;
for (int i = 0; i < numParticles; i++)
for (int j = i+1; j < numParticles; j++)
for (int k = j+1; k < numParticles; k++) {
Vec3 d12 = positions[j]-positions[i];
Vec3 d13 = positions[k]-positions[i];
Vec3 d23 = positions[k]-positions[j];
double r12 = sqrt(d12.dot(d12));
double r13 = sqrt(d13.dot(d13));
double r23 = sqrt(d23.dot(d23));
expectedEnergy += 0.5*(r12+r13+r23)*(c[i]+c[j]+c[k]);
}
ASSERT_EQUAL_TOL(expectedEnergy, state.getPotentialEnergy(), 1e-5);
}
void testTypeFilters() {
// Create a system.
System system;
for (int i = 0; i < 5; i++)
system.addParticle(1.0);
CustomManyParticleForce* force = new CustomManyParticleForce(3, "c1*(distance(p1,p2)+distance(p1,p3))");
force->addPerParticleParameter("c");
double c[] = {1.0, 2.0, 1.3, 1.5, -2.1};
int type[] = {0, 1, 0, 1, 5};
vector<double> params(1);
for (int i = 0; i < 5; i++) {
params[0] = c[i];
force->addParticle(params, type[i]);
}
vector<Vec3> positions;
positions.push_back(Vec3(0, 0, 0));
positions.push_back(Vec3(1, 0, 0));
positions.push_back(Vec3(0, 1.1, 0.3));
positions.push_back(Vec3(0.4, 0, -0.8));
positions.push_back(Vec3(0.2, 0.5, -0.1));
set<int> f1, f2;
f1.insert(0);
f2.insert(1);
f2.insert(5);
force->setTypeFilter(0, f1);
force->setTypeFilter(1, f2);
force->setTypeFilter(2, f2);
system.addForce(force);
VerletIntegrator integrator(0.001);
Context context(system, integrator, platform);
context.setPositions(positions);
// See if the energy is correct.
State state = context.getState(State::Energy);
double expectedEnergy = 0;
int sets[6][3] = {{0,1,3}, {0,1,4}, {0,3,4}, {2,1,3}, {2,1,4}, {2,3,4}};
for (int i = 0; i < 6; i++) {
int p1 = sets[i][0];
int p2 = sets[i][1];
int p3 = sets[i][2];
Vec3 d12 = positions[p2]-positions[p1];
Vec3 d13 = positions[p3]-positions[p1];
double r12 = sqrt(d12.dot(d12));
double r13 = sqrt(d13.dot(d13));
expectedEnergy += c[p1]*(r12+r13);
}
ASSERT_EQUAL_TOL(expectedEnergy, state.getPotentialEnergy(), 1e-5);
}
void testCentralParticleModeNoCutoff() {
CustomManyParticleForce* force = new CustomManyParticleForce(3,
"L*eps*(cos(theta1)+1/3)^2*exp(sigma*gamma/(r12-a*sigma))*exp(sigma*gamma/(r13-a*sigma));"
"r12 = distance(p1,p2); r13 = distance(p1,p3); theta1 = angle(p3,p1,p2)");
force->setPermutationMode(CustomManyParticleForce::UniqueCentralParticle);
force->addGlobalParameter("L", 23.13);
force->addGlobalParameter("eps", 25.894776);
force->addGlobalParameter("a", 1.8);
force->addGlobalParameter("sigma", 0.23925);
force->addGlobalParameter("gamma", 1.2);
vector<double> params;
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
vector<Vec3> positions;
positions.push_back(Vec3(0, 0, 0));
positions.push_back(Vec3(0.1, 0, 0));
positions.push_back(Vec3(0, 0.11, 0.03));
positions.push_back(Vec3(0.04, 0, -0.08));
int sets[12][3] = {{0,1,2}, {0,1,3}, {0,2,3}, {1,0,2}, {1,0,3}, {1, 2, 3}, {2,0,1}, {2,0,3}, {2, 1, 3}, {3,0,1}, {3,0,2}, {3,1,2}};
vector<const int*> expectedSets(&sets[0], &sets[12]);
validateStillingerWeber(force, positions, expectedSets, 2.0);
}
void testCentralParticleModeCutoff() {
CustomManyParticleForce* force = new CustomManyParticleForce(3,
"L*eps*(cos(theta1)+1/3)^2*exp(sigma*gamma/(r12-a*sigma))*exp(sigma*gamma/(r13-a*sigma));"
"r12 = distance(p1,p2); r13 = distance(p1,p3); theta1 = angle(p3,p1,p2)");
force->setPermutationMode(CustomManyParticleForce::UniqueCentralParticle);
force->addGlobalParameter("L", 23.13);
force->addGlobalParameter("eps", 25.894776);
force->addGlobalParameter("a", 1.8);
force->addGlobalParameter("sigma", 0.23925);
force->addGlobalParameter("gamma", 1.2);
force->setNonbondedMethod(CustomManyParticleForce::CutoffNonPeriodic);
force->setCutoffDistance(0.155);
vector<double> params;
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
force->addParticle(params);
vector<Vec3> positions;
positions.push_back(Vec3(0, 0, 0));
positions.push_back(Vec3(0.1, 0, 0));
positions.push_back(Vec3(0, 0.11, 0.03));
positions.push_back(Vec3(0.04, 0, -0.08));
int sets[8][3] = {{0,1,2}, {0,1,3}, {0,2,3}, {1,0,2}, {1,0,3}, {1, 2, 3}, {2,0,1}, {3,0,1}};
vector<const int*> expectedSets(&sets[0], &sets[8]);
validateStillingerWeber(force, positions, expectedSets, 2.0);
}
int main() {
try {
testNoCutoff();
testCutoff();
testPeriodic();
testTriclinic();
testExclusions();
testAllTerms();
testParameters();
testTabulatedFunctions();
testTypeFilters();
testCentralParticleModeNoCutoff();
testCentralParticleModeCutoff();
}
catch(const exception& e) {
cout << "exception: " << e.what() << endl;
return 1;
}
cout << "Done" << endl;
return 0;
void runPlatformTests() {
}
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