482 lines
14 KiB
C++
482 lines
14 KiB
C++
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/* $Id: CopyPose.cpp 20622 2009-06-04 12:47:59Z ben2610 $
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* CopyPose.cpp
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*
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* Created on: Mar 17, 2009
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* Author: benoit bolsee
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*/
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#include "CopyPose.hpp"
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#include "kdl/kinfam_io.hpp"
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#include <math.h>
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#include <malloc.h>
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#include <string.h>
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namespace iTaSC
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{
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const unsigned int maxPoseCacheSize = (2*(3+3*2));
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CopyPose::CopyPose(unsigned int control_output, unsigned int dynamic_output, double armlength, double accuracy, unsigned int maximum_iterations):
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ConstraintSet(),
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m_cache(NULL),
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m_poseCCh(-1),m_poseCTs(0)
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{
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m_maxerror = armlength/2.0;
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m_outputControl = (control_output & CTL_ALL);
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int _nc = nBitsOn(m_outputControl);
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if (!_nc)
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return;
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// reset the constraint set
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reset(_nc, accuracy, maximum_iterations);
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_nc = 0;
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m_nvalues = 0;
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int nrot = 0, npos = 0;
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int nposCache = 0, nrotCache = 0;
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m_outputDynamic = (dynamic_output & m_outputControl);
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memset(m_values, 0, sizeof(m_values));
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memset(m_posData, 0, sizeof(m_posData));
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memset(m_rotData, 0, sizeof(m_rotData));
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memset(&m_rot, 0, sizeof(m_rot));
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memset(&m_pos, 0, sizeof(m_pos));
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if (m_outputControl & CTL_POSITION) {
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m_pos.alpha = 1.0;
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m_pos.K = 20.0;
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m_pos.tolerance = 0.05;
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m_values[m_nvalues].alpha = m_pos.alpha;
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m_values[m_nvalues].feedback = m_pos.K;
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m_values[m_nvalues].tolerance = m_pos.tolerance;
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m_values[m_nvalues].id = ID_POSITION;
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if (m_outputControl & CTL_POSITIONX) {
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m_Wy(_nc) = m_pos.alpha/*/(m_pos.tolerance*m_pos.K)*/;
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m_Cf(_nc++,0)=1.0;
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m_posData[npos++].id = ID_POSITIONX;
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if (m_outputDynamic & CTL_POSITIONX)
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nposCache++;
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}
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if (m_outputControl & CTL_POSITIONY) {
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m_Wy(_nc) = m_pos.alpha/*/(m_pos.tolerance*m_pos.K)*/;
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m_Cf(_nc++,1)=1.0;
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m_posData[npos++].id = ID_POSITIONY;
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if (m_outputDynamic & CTL_POSITIONY)
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nposCache++;
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}
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if (m_outputControl & CTL_POSITIONZ) {
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m_Wy(_nc) = m_pos.alpha/*/(m_pos.tolerance*m_pos.K)*/;
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m_Cf(_nc++,2)=1.0;
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m_posData[npos++].id = ID_POSITIONZ;
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if (m_outputDynamic & CTL_POSITIONZ)
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nposCache++;
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}
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m_values[m_nvalues].number = npos;
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m_values[m_nvalues++].values = m_posData;
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m_pos.firsty = 0;
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m_pos.ny = npos;
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}
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if (m_outputControl & CTL_ROTATION) {
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m_rot.alpha = 1.0;
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m_rot.K = 20.0;
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m_rot.tolerance = 0.05;
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m_values[m_nvalues].alpha = m_rot.alpha;
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m_values[m_nvalues].feedback = m_rot.K;
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m_values[m_nvalues].tolerance = m_rot.tolerance;
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m_values[m_nvalues].id = ID_ROTATION;
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if (m_outputControl & CTL_ROTATIONX) {
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m_Wy(_nc) = m_rot.alpha/*/(m_rot.tolerance*m_rot.K)*/;
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m_Cf(_nc++,3)=1.0;
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m_rotData[nrot++].id = ID_ROTATIONX;
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if (m_outputDynamic & CTL_ROTATIONX)
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nrotCache++;
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}
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if (m_outputControl & CTL_ROTATIONY) {
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m_Wy(_nc) = m_rot.alpha/*/(m_rot.tolerance*m_rot.K)*/;
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m_Cf(_nc++,4)=1.0;
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m_rotData[nrot++].id = ID_ROTATIONY;
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if (m_outputDynamic & CTL_ROTATIONY)
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nrotCache++;
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}
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if (m_outputControl & CTL_ROTATIONZ) {
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m_Wy(_nc) = m_rot.alpha/*/(m_rot.tolerance*m_rot.K)*/;
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m_Cf(_nc++,5)=1.0;
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m_rotData[nrot++].id = ID_ROTATIONZ;
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if (m_outputDynamic & CTL_ROTATIONZ)
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nrotCache++;
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}
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m_values[m_nvalues].number = nrot;
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m_values[m_nvalues++].values = m_rotData;
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m_rot.firsty = npos;
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m_rot.ny = nrot;
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}
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assert(_nc == m_nc);
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m_Jf=e_identity_matrix(6,6);
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m_poseCacheSize = ((nrotCache)?(3+nrotCache*2):0)+((nposCache)?(3+nposCache*2):0);
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}
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CopyPose::~CopyPose()
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{
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}
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bool CopyPose::initialise(Frame& init_pose)
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{
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m_externalPose = m_internalPose = init_pose;
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updateJacobian();
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return true;
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}
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void CopyPose::modelUpdate(Frame& _external_pose,const Timestamp& timestamp)
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{
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m_internalPose = m_externalPose = _external_pose;
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updateJacobian();
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}
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void CopyPose::initCache(Cache *_cache)
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{
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m_cache = _cache;
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m_poseCCh = -1;
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if (m_cache) {
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// create one channel for the coordinates
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m_poseCCh = m_cache->addChannel(this, "Xf", m_poseCacheSize*sizeof(double));
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// don't save initial value, it will be recomputed from external pose
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//pushPose(0);
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}
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}
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double* CopyPose::pushValues(double* item, ControlState* _state, unsigned int mask)
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{
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ControlState::ControlValue* _yval;
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int i;
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*item++ = _state->alpha;
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*item++ = _state->K;
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*item++ = _state->tolerance;
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for (i=0, _yval=_state->output; i<_state->ny; mask<<=1) {
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if (m_outputControl & mask) {
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if (m_outputDynamic & mask) {
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*item++ = _yval->yd;
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*item++ = _yval->yddot;
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}
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_yval++;
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i++;
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}
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}
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return item;
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}
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void CopyPose::pushPose(CacheTS timestamp)
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{
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if (m_poseCCh >= 0) {
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if (m_poseCacheSize) {
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double buf[maxPoseCacheSize];
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double *item = buf;
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if (m_outputDynamic & CTL_POSITION)
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item = pushValues(item, &m_pos, CTL_POSITIONX);
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if (m_outputDynamic & CTL_ROTATION)
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item = pushValues(item, &m_rot, CTL_ROTATIONX);
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m_cache->addCacheVectorIfDifferent(this, m_poseCCh, timestamp, buf, m_poseCacheSize, KDL::epsilon);
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} else
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m_cache->addCacheVectorIfDifferent(this, m_poseCCh, timestamp, NULL, 0, KDL::epsilon);
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m_poseCTs = timestamp;
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}
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}
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double* CopyPose::restoreValues(double* item, ConstraintValues* _values, ControlState* _state, unsigned int mask)
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{
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ConstraintSingleValue* _data;
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ControlState::ControlValue* _yval;
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int i, j;
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_values->alpha = _state->alpha = *item++;
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_values->feedback = _state->K = *item++;
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_values->tolerance = _state->tolerance = *item++;
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for (i=_state->firsty, j=i+_state->ny, _yval=_state->output, _data=_values->values; i<j; mask<<=1) {
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if (m_outputControl & mask) {
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m_Wy(i) = _state->alpha/*/(_state->tolerance*_state->K)*/;
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if (m_outputDynamic & mask) {
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_data->yd = _yval->yd = *item++;
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_data->yddot = _yval->yddot = *item++;
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}
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_data++;
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_yval++;
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i++;
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}
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}
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return item;
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}
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bool CopyPose::popPose(CacheTS timestamp)
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{
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bool found = false;
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if (m_poseCCh >= 0) {
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double *item = (double*)m_cache->getPreviousCacheItem(this, m_poseCCh, ×tamp);
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if (item) {
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found = true;
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if (timestamp != m_poseCTs) {
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int i=0;
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if (m_outputControl & CTL_POSITION) {
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if (m_outputDynamic & CTL_POSITION) {
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item = restoreValues(item, &m_values[i], &m_pos, CTL_POSITIONX);
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}
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i++;
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}
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if (m_outputControl & CTL_ROTATION) {
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if (m_outputDynamic & CTL_ROTATION) {
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item = restoreValues(item, &m_values[i], &m_rot, CTL_ROTATIONX);
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}
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i++;
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}
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m_poseCTs = timestamp;
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item = NULL;
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}
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}
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}
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return found;
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}
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void CopyPose::interpolateOutput(ControlState* _state, unsigned int mask, const Timestamp& timestamp)
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{
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ControlState::ControlValue* _yval;
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int i;
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for (i=0, _yval=_state->output; i<_state->ny; mask <<= 1) {
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if (m_outputControl & mask) {
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if (m_outputDynamic & mask) {
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if (timestamp.substep && timestamp.interpolate) {
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_yval->yd += _yval->yddot*timestamp.realTimestep;
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} else {
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_yval->yd = _yval->nextyd;
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_yval->yddot = _yval->nextyddot;
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}
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}
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i++;
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_yval++;
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}
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}
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}
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void CopyPose::pushCache(const Timestamp& timestamp)
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{
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if (!timestamp.substep && timestamp.cache) {
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pushPose(timestamp.cacheTimestamp);
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}
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}
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void CopyPose::updateKinematics(const Timestamp& timestamp)
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{
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if (timestamp.interpolate) {
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if (m_outputDynamic & CTL_POSITION)
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interpolateOutput(&m_pos, CTL_POSITIONX, timestamp);
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if (m_outputDynamic & CTL_ROTATION)
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interpolateOutput(&m_rot, CTL_ROTATIONX, timestamp);
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}
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pushCache(timestamp);
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}
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void CopyPose::updateJacobian()
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{
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//Jacobian is always identity at the start of the constraint chain
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//instead of going through complicated jacobian operation, implemented direct formula
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//m_Jf(1,3) = m_internalPose.p.z();
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//m_Jf(2,3) = -m_internalPose.p.y();
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//m_Jf(0,4) = -m_internalPose.p.z();
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//m_Jf(2,4) = m_internalPose.p.x();
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//m_Jf(0,5) = m_internalPose.p.y();
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//m_Jf(1,5) = -m_internalPose.p.x();
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}
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void CopyPose::updateState(ConstraintValues* _values, ControlState* _state, unsigned int mask, double timestep)
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{
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int id = (mask == CTL_ROTATIONX) ? ID_ROTATIONX : ID_POSITIONX;
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ControlState::ControlValue* _yval;
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ConstraintSingleValue* _data;
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int i, j, k;
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int action = 0;
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if ((_values->action & ACT_ALPHA) && _values->alpha >= 0.0) {
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_state->alpha = _values->alpha;
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action |= ACT_ALPHA;
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}
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if ((_values->action & ACT_TOLERANCE) && _values->tolerance > KDL::epsilon) {
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_state->tolerance = _values->tolerance;
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action |= ACT_TOLERANCE;
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}
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if ((_values->action & ACT_FEEDBACK) && _values->feedback > KDL::epsilon) {
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_state->K = _values->feedback;
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action |= ACT_FEEDBACK;
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}
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for (i=_state->firsty, j=_state->firsty+_state->ny, _yval=_state->output; i<j; mask <<= 1, id++) {
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if (m_outputControl & mask) {
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if (action)
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m_Wy(i) = _state->alpha/*/(_state->tolerance*_state->K)*/;
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// check if this controlled output is provided
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for (k=0, _data=_values->values; k<_values->number; k++, _data++) {
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if (_data->id == id) {
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switch (_data->action & (ACT_VALUE|ACT_VELOCITY)) {
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case 0:
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// no indication, keep current values
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break;
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case ACT_VELOCITY:
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// only the velocity is given estimate the new value by integration
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_data->yd = _yval->yd+_data->yddot*timestep;
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// walkthrough
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case ACT_VALUE:
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_yval->nextyd = _data->yd;
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// if the user sets the value, we assume future velocity is zero
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// (until the user changes the value again)
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_yval->nextyddot = (_data->action & ACT_VALUE) ? 0.0 : _data->yddot;
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if (timestep>0.0) {
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_yval->yddot = (_data->yd-_yval->yd)/timestep;
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} else {
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// allow the user to change target instantenously when this function
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// if called from setControlParameter with timestep = 0
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_yval->yd = _yval->nextyd;
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_yval->yddot = _yval->nextyddot;
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}
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break;
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case (ACT_VALUE|ACT_VELOCITY):
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// the user should not set the value and velocity at the same time.
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// In this case, we will assume that he wants to set the future value
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// and we compute the current value to match the velocity
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_yval->yd = _data->yd - _data->yddot*timestep;
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_yval->nextyd = _data->yd;
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_yval->nextyddot = _data->yddot;
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if (timestep>0.0) {
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_yval->yddot = (_data->yd-_yval->yd)/timestep;
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} else {
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_yval->yd = _yval->nextyd;
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_yval->yddot = _yval->nextyddot;
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}
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break;
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}
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}
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}
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_yval++;
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i++;
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}
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}
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}
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bool CopyPose::setControlParameters(struct ConstraintValues* _values, unsigned int _nvalues, double timestep)
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{
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while (_nvalues > 0) {
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if (_values->id >= ID_POSITION && _values->id <= ID_POSITIONZ && (m_outputControl & CTL_POSITION)) {
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updateState(_values, &m_pos, CTL_POSITIONX, timestep);
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}
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if (_values->id >= ID_ROTATION && _values->id <= ID_ROTATIONZ && (m_outputControl & CTL_ROTATION)) {
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updateState(_values, &m_rot, CTL_ROTATIONX, timestep);
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}
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_values++;
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_nvalues--;
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}
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return true;
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}
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void CopyPose::updateValues(Vector& vel, ConstraintValues* _values, ControlState* _state, unsigned int mask)
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{
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ConstraintSingleValue* _data;
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ControlState::ControlValue* _yval;
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int i, j;
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_values->action = 0;
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for (i=_state->firsty, j=0, _yval=_state->output, _data=_values->values; j<3; j++, mask<<=1) {
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if (m_outputControl & mask) {
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*(double*)&_data->y = vel(j);
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*(double*)&_data->ydot = m_ydot(i);
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_data->yd = _yval->yd;
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_data->yddot = _yval->yddot;
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_data->action = 0;
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i++;
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_data++;
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_yval++;
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}
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}
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}
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|
void CopyPose::updateOutput(Vector& vel, ControlState* _state, unsigned int mask)
|
||
|
{
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||
|
ControlState::ControlValue* _yval;
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||
|
int i, j;
|
||
|
double coef=1.0;
|
||
|
if (mask & CTL_POSITION) {
|
||
|
// put a limit on position error
|
||
|
double len=0.0;
|
||
|
for (j=0, _yval=_state->output; j<3; j++) {
|
||
|
if (m_outputControl & (mask<<j)) {
|
||
|
len += KDL::sqr(_yval->yd-vel(j));
|
||
|
_yval++;
|
||
|
}
|
||
|
}
|
||
|
len = KDL::sqrt(len);
|
||
|
if (len > m_maxerror)
|
||
|
coef = m_maxerror/len;
|
||
|
}
|
||
|
for (i=_state->firsty, j=0, _yval=_state->output; j<3; j++) {
|
||
|
if (m_outputControl & (mask<<j)) {
|
||
|
m_ydot(i)=_yval->yddot+_state->K*coef*(_yval->yd-vel(j));
|
||
|
_yval++;
|
||
|
i++;
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
|
||
|
void CopyPose::updateControlOutput(const Timestamp& timestamp)
|
||
|
{
|
||
|
//IMO this should be done, no idea if it is enough (wrt Distance impl)
|
||
|
Twist y = diff(F_identity, m_internalPose);
|
||
|
bool found = true;
|
||
|
if (!timestamp.substep) {
|
||
|
if (!timestamp.reiterate) {
|
||
|
found = popPose(timestamp.cacheTimestamp);
|
||
|
}
|
||
|
}
|
||
|
if (m_constraintCallback && (m_substep || (!timestamp.reiterate && !timestamp.substep))) {
|
||
|
// initialize first callback the application to get the current values
|
||
|
int i=0;
|
||
|
if (m_outputControl & CTL_POSITION) {
|
||
|
updateValues(y.vel, &m_values[i++], &m_pos, CTL_POSITIONX);
|
||
|
}
|
||
|
if (m_outputControl & CTL_ROTATION) {
|
||
|
updateValues(y.rot, &m_values[i++], &m_rot, CTL_ROTATIONX);
|
||
|
}
|
||
|
if ((*m_constraintCallback)(timestamp, m_values, m_nvalues, m_constraintParam)) {
|
||
|
setControlParameters(m_values, m_nvalues, (found && timestamp.interpolate)?timestamp.realTimestep:0.0);
|
||
|
}
|
||
|
}
|
||
|
if (m_outputControl & CTL_POSITION) {
|
||
|
updateOutput(y.vel, &m_pos, CTL_POSITIONX);
|
||
|
}
|
||
|
if (m_outputControl & CTL_ROTATION) {
|
||
|
updateOutput(y.rot, &m_rot, CTL_ROTATIONX);
|
||
|
}
|
||
|
}
|
||
|
|
||
|
const ConstraintValues* CopyPose::getControlParameters(unsigned int* _nvalues)
|
||
|
{
|
||
|
Twist y = diff(m_internalPose,F_identity);
|
||
|
int i=0;
|
||
|
if (m_outputControl & CTL_POSITION) {
|
||
|
updateValues(y.vel, &m_values[i++], &m_pos, CTL_POSITIONX);
|
||
|
}
|
||
|
if (m_outputControl & CTL_ROTATION) {
|
||
|
updateValues(y.rot, &m_values[i++], &m_rot, CTL_ROTATIONX);
|
||
|
}
|
||
|
if (_nvalues)
|
||
|
*_nvalues=m_nvalues;
|
||
|
return m_values;
|
||
|
}
|
||
|
|
||
|
double CopyPose::getMaxTimestep(double& timestep)
|
||
|
{
|
||
|
// CopyPose should not have any limit on linear velocity:
|
||
|
// in case the target is out of reach, this can be very high.
|
||
|
// We will simply limit on rotation
|
||
|
e_scalar maxChidot = m_chidot.block(3,0,3,1).cwise().abs().maxCoeff();
|
||
|
if (timestep*maxChidot > m_maxDeltaChi) {
|
||
|
timestep = m_maxDeltaChi/maxChidot;
|
||
|
}
|
||
|
return timestep;
|
||
|
}
|
||
|
|
||
|
}
|