int main(int argc, char **argv) { int num_segments = 3; vector<double> segment_times = generateSegmentTimes(num_segments); double x0 = uniform(generator); double xd0 = uniform(generator); double xf = uniform(generator); double xdf = uniform(generator); double x1 = uniform(generator); double x2 = uniform(generator); PiecewisePolynomial<double> result = twoWaypointCubicSpline(segment_times, x0, xd0, xf, xdf, x1, x2); for (int i = 0; i < num_segments; i++) { valuecheck(segment_times[i], result.getStartTime(i)); } valuecheck(segment_times[num_segments], result.getEndTime(num_segments - 1)); // check value constraints double tol = 1e-10; PiecewisePolynomial<double> derivative = result.derivative(); PiecewisePolynomial<double> second_derivative = derivative.derivative(); valuecheck(result.value(result.getStartTime(0)), x0, tol); valuecheck(derivative.value(result.getStartTime(0)), xd0, tol); valuecheck(result.value(result.getEndTime(num_segments - 1)), xf, tol); valuecheck(derivative.value(result.getEndTime(num_segments - 1)), xdf, tol); valuecheck(result.value(result.getStartTime(1)), x1, tol); valuecheck(result.value(result.getStartTime(2)), x2, tol); // check continuity constraints double eps = 1e-10; int num_knots = num_segments - 1; for (int i = 0; i < num_knots; i++) { double t_knot = result.getEndTime(i); valuecheck(result.value(t_knot - eps), result.value(t_knot + eps), 1e-8); valuecheck(derivative.value(t_knot - eps), derivative.value(t_knot + eps), 1e-8); valuecheck(second_derivative.value(t_knot - eps), second_derivative.value(t_knot + eps), 1e-8); } #if !defined(WIN32) && !defined(WIN64) int ntests = 1000; cout << "time: " << measure<chrono::microseconds>::execution(randomSpeedTest, ntests) / (double) ntests << " microseconds." << endl; #endif cout << "test passed" << endl; return 0; }
void mexFunction(int nlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[]) { string usage = "[coefs, objval] = nWaypointCubicSplinemex(ts, xs, xd0, xdf)"; if (nrhs != 4) mexErrMsgIdAndTxt("Drake:nWaypointCubicSplinemex:WrongNumberOfInputs", usage.c_str()); if (nlhs > 2) mexErrMsgIdAndTxt("Drake:nWaypointCubicSplinemex:WrongNumberOfOutputs", usage.c_str()); const std::vector<double> segment_times = matlabToStdVector<double>(prhs[0]); MatrixXd xs = matlabToEigen<Dynamic, Dynamic>(prhs[1]); auto xd0 = matlabToEigen<Dynamic, 1>(prhs[2]); auto xdf = matlabToEigen<Dynamic, 1>(prhs[3]); mwSize ndof = static_cast<mwSize>(xs.rows()); mwSize num_segments = static_cast<mwSize>(xs.cols()) - 1; mwSize num_knots = num_segments - 1; mwSize num_coeffs_per_segment = 4; mwSize dims[] = {ndof, num_segments, num_coeffs_per_segment}; plhs[0] = mxCreateNumericArray(3, dims, mxDOUBLE_CLASS, mxREAL); double objective_value = 0.0; for (mwSize dof = 0; dof < ndof; dof++) { VectorXd xi = xs.block(dof, 1, 1, num_knots).transpose(); PiecewisePolynomial<double> spline = nWaypointCubicSpline(segment_times, xs(dof, 0), xd0[dof], xs(dof, num_segments), xdf[dof], xi); PiecewisePolynomial<double> acceleration_squared = spline.derivative(2); acceleration_squared *= acceleration_squared; PiecewisePolynomial<double> acceleration_squared_integral = acceleration_squared.integral(); objective_value += acceleration_squared_integral.scalarValue(spline.getEndTime()) - acceleration_squared_integral.scalarValue(spline.getStartTime()); for (mwSize segment_index = 0; segment_index < spline.getNumberOfSegments(); segment_index++) { for (mwSize coefficient_index = 0; coefficient_index < num_coeffs_per_segment; coefficient_index++) { mwSize sub[] = {dof, segment_index, num_coeffs_per_segment - coefficient_index - 1 }; // Matlab's reverse coefficient indexing... *(mxGetPr(plhs[0]) + sub2ind(3, dims, sub)) = spline.getPolynomial(static_cast<int>(segment_index)) .getCoefficients()[coefficient_index]; } } } if (nlhs > 1) { plhs[1] = mxCreateDoubleScalar(objective_value); } }
void mexFunction(int nlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[]) { string usage = "[coefs, ts, objective_value] = " "nWaypointCubicSplineFreeKnotTimesmex.cpp(t0, tf, xs, xd0, xdf)"; if (nrhs != 5) mexErrMsgIdAndTxt( "Drake:nWaypointCubicSplineFreeKnotTimesmex.cpp:WrongNumberOfInputs", usage.c_str()); if (nlhs < 2 || nlhs > 3) mexErrMsgIdAndTxt( "Drake:nWaypointCubicSplineFreeKnotTimesmex.cpp:WrongNumberOfOutputs", usage.c_str()); double t0 = mxGetPrSafe(prhs[0])[0]; double tf = mxGetPrSafe(prhs[1])[0]; MatrixXd xs = matlabToEigen<Dynamic, Dynamic>(prhs[2]); auto xd0 = matlabToEigen<Dynamic, 1>(prhs[3]); auto xdf = matlabToEigen<Dynamic, 1>(prhs[4]); mwSize ndof = static_cast<mwSize>(xs.rows()); mwSize num_segments = static_cast<mwSize>(xs.cols()) - 1; mwSize num_knots = num_segments - 1; if (num_knots >= 3) mexWarnMsgTxt( "More knots than two is likely to be super slow in a grid search!\n"); if (num_knots <= 0) mexErrMsgIdAndTxt( "Drake:nWaypointCubicSplineFreeKnotTimesmex.cpp:" "NotEnoughKnotsToJustifyThisFunction", usage.c_str()); mwSize num_coeffs_per_segment = 4; mwSize dims[] = {ndof, num_segments, num_coeffs_per_segment}; plhs[0] = mxCreateNumericArray(3, dims, mxDOUBLE_CLASS, mxREAL); std::vector<double> segment_times; segment_times.resize(static_cast<size_t>(num_segments) + 1); segment_times[0] = t0; segment_times[static_cast<size_t>(num_segments)] = tf; std::vector<double> best_segment_times = segment_times; double t_step = (tf - t0) / GRID_STEPS; double min_objective_value = numeric_limits<double>::infinity(); // assemble the knot point locations for input to nWaypointCubicSpline MatrixXd xi = xs.block(0, 1, ndof, num_knots); if (GRID_STEPS <= num_knots) { // If we have have too few grid steps, then by pigeonhole it's // impossible to give each a unique time in our grid search. mexErrMsgIdAndTxt( "Drake:nWaypointCubicSplineFreeKnotTimesmex.cpp:" "TooManyKnotsForNumGridSteps", usage.c_str()); } std::vector<int> t_indices; t_indices.reserve(num_knots); for (mwSize i = 0; i < num_knots; i++) { t_indices.push_back(i + 1); // assume knot point won't be the same time as // the initial state, or previous knot point } while (t_indices[0] < (GRID_STEPS - static_cast<int>(num_knots) + 1)) { for (mwSize i = 0; i < num_knots; i++) segment_times[i + 1] = t0 + t_indices[i] * t_step; bool valid_solution = true; double objective_value = 0.0; for (mwSize dof = 0; dof < ndof && valid_solution; dof++) { try { PiecewisePolynomial<double> spline = nWaypointCubicSpline( segment_times, xs(dof, 0), xd0[dof], xs(dof, num_segments), xdf[dof], xi.row(dof).transpose()); PiecewisePolynomial<double> acceleration_squared = spline.derivative(2); acceleration_squared *= acceleration_squared; PiecewisePolynomial<double> acceleration_squared_integral = acceleration_squared.integral(); objective_value += acceleration_squared_integral.scalarValue(spline.getEndTime()) - acceleration_squared_integral.scalarValue(spline.getStartTime()); } catch (ConstraintMatrixSingularError &) { valid_solution = false; } } if (valid_solution && objective_value < min_objective_value) { best_segment_times = segment_times; min_objective_value = objective_value; } // Advance grid search counter or terminate, counting from // the latest t_index, and on overflow carrying to the // next lowest t_index and resetting to the new value of that // next lowest t_index. (since times must always be in order!) t_indices[num_knots - 1]++; // carry, except for the lowest place, which we // use to detect doneness. for (size_t i = num_knots - 1; i > 0; i--) { if ((i == num_knots - 1 && t_indices[i] >= GRID_STEPS) || (i < num_knots - 1 && t_indices[i] >= t_indices[i + 1])) { t_indices[i - 1]++; t_indices[i] = t_indices[i - 1] + 1; } } } for (mwSize dof = 0; dof < ndof; dof++) { PiecewisePolynomial<double> spline = nWaypointCubicSpline( best_segment_times, xs(dof, 0), xd0[dof], xs(dof, num_segments), xdf[dof], xi.row(dof).transpose()); for (mwSize segment_index = 0; segment_index < static_cast<mwSize>(spline.getNumberOfSegments()); segment_index++) { for (mwSize coefficient_index = 0; coefficient_index < num_coeffs_per_segment; coefficient_index++) { mwSize sub[] = {dof, segment_index, num_coeffs_per_segment - coefficient_index - 1}; // Matlab's reverse coefficient indexing... *(mxGetPr(plhs[0]) + sub2ind(3, dims, sub)) = spline.getPolynomial(static_cast<int>(segment_index)) .GetCoefficients()[coefficient_index]; } } } plhs[1] = stdVectorToMatlab(best_segment_times); if (nlhs > 2) plhs[2] = mxCreateDoubleScalar(min_objective_value); }
void mexFunction(int nlhs, mxArray *plhs[],int nrhs, const mxArray *prhs[]) { string usage = "[coefs, ts, objective_value] = twoWaypointCubicSplineFreeKnotTimesmex.cpp(t0, tf, xs, xd0, xdf)"; if (nrhs != 5) mexErrMsgIdAndTxt("Drake:twoWaypointCubicSplineFreeKnotTimesmex.cpp:WrongNumberOfInputs", usage.c_str()); if (nlhs < 2 || nlhs > 3) mexErrMsgIdAndTxt("Drake:twoWaypointCubicSplineFreeKnotTimesmex.cpp:WrongNumberOfOutputs", usage.c_str()); double t0 = mxGetPrSafe(prhs[0])[0]; double tf = mxGetPrSafe(prhs[1])[0]; MatrixXd xs = matlabToEigen<Dynamic, Dynamic>(prhs[2]); auto xd0 = matlabToEigen<Dynamic, 1>(prhs[3]); auto xdf = matlabToEigen<Dynamic, 1>(prhs[4]); mwSize ndof = static_cast<mwSize>(xs.rows()); mwSize num_segments = 3; mwSize num_coeffs_per_segment = 4; mwSize dims[] = {ndof, num_segments, num_coeffs_per_segment}; plhs[0] = mxCreateNumericArray(num_segments, dims, mxDOUBLE_CLASS, mxREAL); std::vector<double> segment_times; segment_times.resize(static_cast<size_t>(num_segments) + 1); segment_times[0] = t0; segment_times[static_cast<size_t>(num_segments)] = tf; std::vector<double> best_segment_times = segment_times; double t_step = (tf - t0) / GRID_STEPS; double min_objective_value = numeric_limits<double>::infinity(); for (int t1_index = 0; t1_index < GRID_STEPS; t1_index++) { segment_times[1] = t0 + t1_index * t_step; for (int t2_index = t1_index; t2_index < GRID_STEPS; t2_index++) { segment_times[2] = t0 + t2_index * t_step; bool valid_solution = true; double objective_value = 0.0; for (int dof = 0; dof < ndof && valid_solution; dof++) { try { PiecewisePolynomial<double> spline = twoWaypointCubicSpline(segment_times, xs(dof, 0), xd0[dof], xs(dof, 3), xdf[dof], xs(dof, 1), xs(dof, 2)); PiecewisePolynomial<double> acceleration_squared = spline.derivative(2); acceleration_squared *= acceleration_squared; PiecewisePolynomial<double> acceleration_squared_integral = acceleration_squared.integral(); objective_value += acceleration_squared_integral.value(spline.getEndTime()) - acceleration_squared_integral.value(spline.getStartTime()); } catch (ConstraintMatrixSingularError&) { valid_solution = false; } } if (valid_solution && objective_value < min_objective_value) { best_segment_times[1] = segment_times[1]; best_segment_times[2] = segment_times[2]; min_objective_value = objective_value; } } } for (mwSize dof = 0; dof < ndof; dof++) { PiecewisePolynomial<double> spline = twoWaypointCubicSpline(best_segment_times, xs(dof, 0), xd0[dof], xs(dof, 3), xdf[dof], xs(dof, 1), xs(dof, 2)); for (mwSize segment_index = 0; segment_index < spline.getNumberOfSegments(); segment_index++) { for (mwSize coefficient_index = 0; coefficient_index < num_coeffs_per_segment; coefficient_index++) { mwSize sub[] = {dof, segment_index, num_coeffs_per_segment - coefficient_index - 1}; // Matlab's reverse coefficient indexing... *(mxGetPr(plhs[0]) + sub2ind(3, dims, sub)) = spline.getPolynomial(segment_index).getCoefficients()[coefficient_index]; } } } plhs[1] = stdVectorToMatlab(best_segment_times); if (nlhs > 2) plhs[2] = mxCreateDoubleScalar(min_objective_value); }