blender/intern/iksolver/extern/IK_solver.h

/*
 * ***** BEGIN GPL LICENSE BLOCK *****
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
 *
 * The Original Code is Copyright (C) 2001-2002 by NaN Holding BV.
 * All rights reserved.
 *
 * The Original Code is: all of this file.
 *
 * Original author: Laurence
 * Contributor(s): Brecht
 *
 * ***** END GPL LICENSE BLOCK *****
 */

/** \file iksolver/extern/IK_solver.h
 *  \ingroup iksolver
 */


/**

 * Copyright (C) 2001 NaN Technologies B.V.
 *
 * @author Laurence, Brecht
 * @mainpage IK - Blender inverse kinematics module.
 *
 * @section about About the IK module
 *
 * This module allows you to create segments and form them into 
 * tree. You can then define a goal points that the end of a given 
 * segment should attempt to reach - an inverse kinematic problem.
 * This module will then modify the segments in the tree in order
 * to get the as near as possible to the goal. This solver uses an
 * inverse jacobian method to find a solution.
 * 
 * @section issues Known issues with this IK solver.
 *
 * - There is currently no support for joint constraints in the
 * solver. This is within the realms of possibility - please ask
 * if this functionality is required.
 * - The solver is slow, inverse jacobian methods in general give
 * 'smooth' solutions and the method is also very flexible, it 
 * does not rely on specific angle parameterization and can be 
 * extended to deal with different joint types and joint 
 * constraints. However it is not suitable for real time use. 
 * Other algorithms exist which are more suitable for real-time
 * applications, please ask if this functionality is required.     
 * 
 * @section dependencies Dependencies
 * 
 * This module only depends on Moto.
 */

#ifndef __IK_SOLVER_H__
#define __IK_SOLVER_H__

#ifdef __cplusplus
extern "C" {
#endif

/**
 * Typical order of calls for solving an IK problem:
 *
 * - create number of IK_Segment's and set their parents and transforms
 * - create an IK_Solver
 * - set a number of goals for the IK_Solver to solve
 * - call IK_Solve
 * - free the IK_Solver
 * - get basis and translation changes from segments
 * - free all segments
 */

/**
 * IK_Segment defines a single segment of an IK tree. 
 * - Individual segments are always defined in local coordinates.
 * - The segment is assumed to be oriented in the local 
 *   y-direction.
 * - start is the start of the segment relative to the end 
 *   of the parent segment.
 * - rest_basis is a column major matrix defineding the rest
 *   position (w.r.t. which the limits are defined), must
 *   be a pure rotation
 * - basis is a column major matrix defining the current change
 *   from the rest basis, must be a pure rotation
 * - length is the length of the bone.  
 *
 * - basis_change and translation_change respectively define
 *   the change in rotation or translation. basis_change is a
 *   column major 3x3 matrix.
 *
 * The local transformation is then defined as:
 * start * rest_basis * basis * basis_change * translation_change * translate(0,length,0) 
 *
 */

typedef void IK_Segment;

enum IK_SegmentFlag {
	IK_XDOF = 1,
	IK_YDOF = 2,
	IK_ZDOF = 4,
	IK_TRANS_XDOF = 8,
	IK_TRANS_YDOF = 16,
	IK_TRANS_ZDOF = 32
};

typedef enum IK_SegmentAxis {
	IK_X = 0,
	IK_Y = 1,
	IK_Z = 2,
	IK_TRANS_X = 3,
	IK_TRANS_Y = 4,
	IK_TRANS_Z = 5
} IK_SegmentAxis;

extern IK_Segment *IK_CreateSegment(int flag);
extern void IK_FreeSegment(IK_Segment *seg);

extern void IK_SetParent(IK_Segment *seg, IK_Segment *parent);
extern void IK_SetTransform(IK_Segment *seg, float start[3], float rest_basis[][3], float basis[][3], float length);
extern void IK_SetLimit(IK_Segment *seg, IK_SegmentAxis axis, float lmin, float lmax);
extern void IK_SetStiffness(IK_Segment *seg, IK_SegmentAxis axis, float stiffness);

extern void IK_GetBasisChange(IK_Segment *seg, float basis_change[][3]);
extern void IK_GetTranslationChange(IK_Segment *seg, float *translation_change);

/**
 * An IK_Solver must be created to be able to execute the solver.
 * 
 * An arbitray number of goals can be created, stating that a given
 * end effector must have a given position or rotation. If multiple
 * goals are specified, they can be weighted (range 0..1) to get
 * some control over their importance.
 * 
 * IK_Solve will execute the solver, that will run until either the
 * system converges, or a maximum number of iterations is reached.
 * It returns 1 if the system converged, 0 otherwise.
 */ 

typedef void IK_Solver;

IK_Solver *IK_CreateSolver(IK_Segment *root);
void IK_FreeSolver(IK_Solver *solver);

void IK_SolverAddGoal(IK_Solver *solver, IK_Segment *tip, float goal[3], float weight);
void IK_SolverAddGoalOrientation(IK_Solver *solver, IK_Segment *tip, float goal[][3], float weight);
void IK_SolverSetPoleVectorConstraint(IK_Solver *solver, IK_Segment *tip, float goal[3], float polegoal[3], float poleangle, int getangle);
float IK_SolverGetPoleAngle(IK_Solver *solver);

int IK_Solve(IK_Solver *solver, float tolerance, int max_iterations);

#define IK_STRETCH_STIFF_EPS 0.01f
#define IK_STRETCH_STIFF_MIN 0.001f
#define IK_STRETCH_STIFF_MAX 1e10

#ifdef __cplusplus
}
#endif

#endif // __IK_SOLVER_H__