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com.badlogic.gdx.physics.bullet.linearmath.btVector3 Maven / Gradle / Ivy
/* ----------------------------------------------------------------------------
* This file was automatically generated by SWIG (http://www.swig.org).
* Version 3.0.11
*
* Do not make changes to this file unless you know what you are doing--modify
* the SWIG interface file instead.
* ----------------------------------------------------------------------------- */
package com.badlogic.gdx.physics.bullet.linearmath;
import com.badlogic.gdx.physics.bullet.BulletBase;
import com.badlogic.gdx.math.Vector3;
import com.badlogic.gdx.math.Quaternion;
import com.badlogic.gdx.math.Matrix3;
import com.badlogic.gdx.math.Matrix4;
public class btVector3 extends BulletBase {
private long swigCPtr;
protected btVector3(final String className, long cPtr, boolean cMemoryOwn) {
super(className, cPtr, cMemoryOwn);
swigCPtr = cPtr;
}
/** Construct a new btVector3, normally you should not need this constructor it's intended for low-level usage. */
public btVector3(long cPtr, boolean cMemoryOwn) {
this("btVector3", cPtr, cMemoryOwn);
construct();
}
@Override
protected void reset(long cPtr, boolean cMemoryOwn) {
if (!destroyed)
destroy();
super.reset(swigCPtr = cPtr, cMemoryOwn);
}
public static long getCPtr(btVector3 obj) {
return (obj == null) ? 0 : obj.swigCPtr;
}
@Override
protected void finalize() throws Throwable {
if (!destroyed)
destroy();
super.finalize();
}
@Override protected synchronized void delete() {
if (swigCPtr != 0) {
if (swigCMemOwn) {
swigCMemOwn = false;
LinearMathJNI.delete_btVector3(swigCPtr);
}
swigCPtr = 0;
}
super.delete();
}
public long operatorNew(long sizeInBytes) {
return LinearMathJNI.btVector3_operatorNew__SWIG_0(swigCPtr, this, sizeInBytes);
}
public void operatorDelete(long ptr) {
LinearMathJNI.btVector3_operatorDelete__SWIG_0(swigCPtr, this, ptr);
}
public long operatorNew(long arg0, long ptr) {
return LinearMathJNI.btVector3_operatorNew__SWIG_1(swigCPtr, this, arg0, ptr);
}
public void operatorDelete(long arg0, long arg1) {
LinearMathJNI.btVector3_operatorDelete__SWIG_1(swigCPtr, this, arg0, arg1);
}
public long operatorNewArray(long sizeInBytes) {
return LinearMathJNI.btVector3_operatorNewArray__SWIG_0(swigCPtr, this, sizeInBytes);
}
public void operatorDeleteArray(long ptr) {
LinearMathJNI.btVector3_operatorDeleteArray__SWIG_0(swigCPtr, this, ptr);
}
public long operatorNewArray(long arg0, long ptr) {
return LinearMathJNI.btVector3_operatorNewArray__SWIG_1(swigCPtr, this, arg0, ptr);
}
public void operatorDeleteArray(long arg0, long arg1) {
LinearMathJNI.btVector3_operatorDeleteArray__SWIG_1(swigCPtr, this, arg0, arg1);
}
public void setFloats(float[] value) {
LinearMathJNI.btVector3_floats_set(swigCPtr, this, value);
}
public float[] getFloats() {
return LinearMathJNI.btVector3_floats_get(swigCPtr, this);
}
public btVector3() {
this(LinearMathJNI.new_btVector3__SWIG_0(), true);
}
public btVector3(float _x, float _y, float _z) {
this(LinearMathJNI.new_btVector3__SWIG_1(_x, _y, _z), true);
}
public Vector3 operatorAdditionAssignment(Vector3 v) {
return LinearMathJNI.btVector3_operatorAdditionAssignment(swigCPtr, this, v);
}
public Vector3 operatorSubtractionAssignment(Vector3 v) {
return LinearMathJNI.btVector3_operatorSubtractionAssignment(swigCPtr, this, v);
}
public Vector3 operatorMultiplicationAssignment(float s) {
return LinearMathJNI.btVector3_operatorMultiplicationAssignment__SWIG_0(swigCPtr, this, s);
}
public Vector3 operatorDivisionAssignment(float s) {
return LinearMathJNI.btVector3_operatorDivisionAssignment(swigCPtr, this, s);
}
public float dot(Vector3 v) {
return LinearMathJNI.btVector3_dot(swigCPtr, this, v);
}
public float length2() {
return LinearMathJNI.btVector3_length2(swigCPtr, this);
}
public float length() {
return LinearMathJNI.btVector3_length(swigCPtr, this);
}
public float norm() {
return LinearMathJNI.btVector3_norm(swigCPtr, this);
}
public float safeNorm() {
return LinearMathJNI.btVector3_safeNorm(swigCPtr, this);
}
public float distance2(Vector3 v) {
return LinearMathJNI.btVector3_distance2(swigCPtr, this, v);
}
public float distance(Vector3 v) {
return LinearMathJNI.btVector3_distance(swigCPtr, this, v);
}
public Vector3 safeNormalize() {
return LinearMathJNI.btVector3_safeNormalize(swigCPtr, this);
}
public Vector3 normalize() {
return LinearMathJNI.btVector3_normalize(swigCPtr, this);
}
public Vector3 normalized() {
return LinearMathJNI.btVector3_normalized(swigCPtr, this);
}
public Vector3 rotate(Vector3 wAxis, float angle) {
return LinearMathJNI.btVector3_rotate(swigCPtr, this, wAxis, angle);
}
public float angle(Vector3 v) {
return LinearMathJNI.btVector3_angle(swigCPtr, this, v);
}
public Vector3 absolute() {
return LinearMathJNI.btVector3_absolute(swigCPtr, this);
}
public Vector3 cross(Vector3 v) {
return LinearMathJNI.btVector3_cross(swigCPtr, this, v);
}
public float triple(Vector3 v1, Vector3 v2) {
return LinearMathJNI.btVector3_triple(swigCPtr, this, v1, v2);
}
public int minAxis() {
return LinearMathJNI.btVector3_minAxis(swigCPtr, this);
}
public int maxAxis() {
return LinearMathJNI.btVector3_maxAxis(swigCPtr, this);
}
public int furthestAxis() {
return LinearMathJNI.btVector3_furthestAxis(swigCPtr, this);
}
public int closestAxis() {
return LinearMathJNI.btVector3_closestAxis(swigCPtr, this);
}
public void setInterpolate3(Vector3 v0, Vector3 v1, float rt) {
LinearMathJNI.btVector3_setInterpolate3(swigCPtr, this, v0, v1, rt);
}
public Vector3 lerp(Vector3 v, float t) {
return LinearMathJNI.btVector3_lerp(swigCPtr, this, v, t);
}
public Vector3 operatorMultiplicationAssignment(Vector3 v) {
return LinearMathJNI.btVector3_operatorMultiplicationAssignment__SWIG_1(swigCPtr, this, v);
}
public float getX() {
return LinearMathJNI.btVector3_getX(swigCPtr, this);
}
public float getY() {
return LinearMathJNI.btVector3_getY(swigCPtr, this);
}
public float getZ() {
return LinearMathJNI.btVector3_getZ(swigCPtr, this);
}
public void setX(float _x) {
LinearMathJNI.btVector3_setX(swigCPtr, this, _x);
}
public void setY(float _y) {
LinearMathJNI.btVector3_setY(swigCPtr, this, _y);
}
public void setZ(float _z) {
LinearMathJNI.btVector3_setZ(swigCPtr, this, _z);
}
public void setW(float _w) {
LinearMathJNI.btVector3_setW(swigCPtr, this, _w);
}
public float x() {
return LinearMathJNI.btVector3_x(swigCPtr, this);
}
public float y() {
return LinearMathJNI.btVector3_y(swigCPtr, this);
}
public float z() {
return LinearMathJNI.btVector3_z(swigCPtr, this);
}
public float w() {
return LinearMathJNI.btVector3_w(swigCPtr, this);
}
public java.nio.FloatBuffer operatorbtScalarPtr() {
return LinearMathJNI.btVector3_operatorbtScalarPtr(swigCPtr, this);
}
public java.nio.FloatBuffer operatorbtConstScalarPtr() {
return LinearMathJNI.btVector3_operatorbtConstScalarPtr(swigCPtr, this);
}
public boolean operatorEqualTo(Vector3 other) {
return LinearMathJNI.btVector3_operatorEqualTo(swigCPtr, this, other);
}
public boolean operatorNotEqualTo(Vector3 other) {
return LinearMathJNI.btVector3_operatorNotEqualTo(swigCPtr, this, other);
}
public void setMax(Vector3 other) {
LinearMathJNI.btVector3_setMax(swigCPtr, this, other);
}
public void setMin(Vector3 other) {
LinearMathJNI.btVector3_setMin(swigCPtr, this, other);
}
public void setValue(float _x, float _y, float _z) {
LinearMathJNI.btVector3_setValue(swigCPtr, this, _x, _y, _z);
}
public void getSkewSymmetricMatrix(btVector3 v0, btVector3 v1, btVector3 v2) {
LinearMathJNI.btVector3_getSkewSymmetricMatrix(swigCPtr, this, btVector3.getCPtr(v0), v0, btVector3.getCPtr(v1), v1, btVector3.getCPtr(v2), v2);
}
public void setZero() {
LinearMathJNI.btVector3_setZero(swigCPtr, this);
}
public boolean isZero() {
return LinearMathJNI.btVector3_isZero(swigCPtr, this);
}
public boolean fuzzyZero() {
return LinearMathJNI.btVector3_fuzzyZero(swigCPtr, this);
}
public void serialize(btVector3FloatData dataOut) {
LinearMathJNI.btVector3_serialize(swigCPtr, this, btVector3FloatData.getCPtr(dataOut), dataOut);
}
public void deSerialize(btVector3FloatData dataIn) {
LinearMathJNI.btVector3_deSerialize(swigCPtr, this, btVector3FloatData.getCPtr(dataIn), dataIn);
}
public void serializeFloat(btVector3FloatData dataOut) {
LinearMathJNI.btVector3_serializeFloat(swigCPtr, this, btVector3FloatData.getCPtr(dataOut), dataOut);
}
public void deSerializeFloat(btVector3FloatData dataIn) {
LinearMathJNI.btVector3_deSerializeFloat(swigCPtr, this, btVector3FloatData.getCPtr(dataIn), dataIn);
}
public void serializeDouble(btVector3DoubleData dataOut) {
LinearMathJNI.btVector3_serializeDouble(swigCPtr, this, btVector3DoubleData.getCPtr(dataOut), dataOut);
}
public void deSerializeDouble(btVector3DoubleData dataIn) {
LinearMathJNI.btVector3_deSerializeDouble(swigCPtr, this, btVector3DoubleData.getCPtr(dataIn), dataIn);
}
public int maxDot(btVector3 array, int array_count, SWIGTYPE_p_float dotOut) {
return LinearMathJNI.btVector3_maxDot(swigCPtr, this, btVector3.getCPtr(array), array, array_count, SWIGTYPE_p_float.getCPtr(dotOut));
}
public int minDot(btVector3 array, int array_count, SWIGTYPE_p_float dotOut) {
return LinearMathJNI.btVector3_minDot(swigCPtr, this, btVector3.getCPtr(array), array, array_count, SWIGTYPE_p_float.getCPtr(dotOut));
}
public Vector3 dot3(Vector3 v0, Vector3 v1, Vector3 v2) {
return LinearMathJNI.btVector3_dot3(swigCPtr, this, v0, v1, v2);
}
}
