public class Matrix4
extends java.lang.Object
implements java.io.Serializable
Vector3
class it allows the chaining of methods by returning a reference to itself. For example:
Matrix4 mat = new Matrix4().trn(position).mul(camera.combined);
Modifier and Type  Field and Description 

static int 
M00
XX: Typically the unrotated X component for scaling, also the cosine of the angle when rotated on the Y and/or Z axis.

static int 
M01
XY: Typically the negative sine of the angle when rotated on the Z axis.

static int 
M02
XZ: Typically the sine of the angle when rotated on the Y axis.

static int 
M03
XW: Typically the translation of the X component.

static int 
M10
YX: Typically the sine of the angle when rotated on the Z axis.

static int 
M11
YY: Typically the unrotated Y component for scaling, also the cosine of the angle when rotated on the X and/or Z axis.

static int 
M12
YZ: Typically the negative sine of the angle when rotated on the X axis.

static int 
M13
YW: Typically the translation of the Y component.

static int 
M20
ZX: Typically the negative sine of the angle when rotated on the Y axis.

static int 
M21
ZY: Typical the sine of the angle when rotated on the X axis.

static int 
M22
ZZ: Typically the unrotated Z component for scaling, also the cosine of the angle when rotated on the X and/or Y axis.

static int 
M23
ZW: Typically the translation of the Z component.

static int 
M30
WX: Typically the value zero.

static int 
M31
WY: Typically the value zero.

static int 
M32
WZ: Typically the value zero.

static int 
M33
WW: Typically the value one.

float[] 
val 
Constructor and Description 

Matrix4()
Constructs an identity matrix

Matrix4(float[] values)
Constructs a matrix from the given float array.

Matrix4(Matrix4 matrix)
Constructs a matrix from the given matrix.

Matrix4(Quaternion quaternion)
Constructs a rotation matrix from the given
Quaternion . 
Matrix4(Vector3 position,
Quaternion rotation,
Vector3 scale)
Construct a matrix from the given translation, rotation and scale.

Modifier and Type  Method and Description 

Matrix4 
avg(Matrix4[] t)
Averages the given transforms and stores the result in this matrix.

Matrix4 
avg(Matrix4[] t,
float[] w)
Averages the given transforms with the given weights and stores the result in this matrix.

Matrix4 
avg(Matrix4 other,
float w)
Averages the given transform with this one and stores the result in this matrix.

Matrix4 
cpy() 
float 
det() 
static float 
det(float[] values)
Computes the determinante of the given matrix.

float 
det3x3() 
void 
extract4x3Matrix(float[] dst)
Copies the 4x3 upperleft submatrix into float array.

Quaternion 
getRotation(Quaternion rotation)
Gets the rotation of this matrix.

Quaternion 
getRotation(Quaternion rotation,
boolean normalizeAxes)
Gets the rotation of this matrix.

Vector3 
getScale(Vector3 scale) 
float 
getScaleX() 
float 
getScaleXSquared() 
float 
getScaleY() 
float 
getScaleYSquared() 
float 
getScaleZ() 
float 
getScaleZSquared() 
Vector3 
getTranslation(Vector3 position) 
float[] 
getValues() 
boolean 
hasRotationOrScaling() 
Matrix4 
idt()
Sets the matrix to an identity matrix.

Matrix4 
inv()
Inverts the matrix.

static boolean 
inv(float[] values)
Computes the inverse of the given matrix.

Matrix4 
lerp(Matrix4 matrix,
float alpha)
Linearly interpolates between this matrix and the given matrix mixing by alpha

static void 
mul(float[] mata,
float[] matb)
Multiplies the matrix mata with matrix matb, storing the result in mata.

Matrix4 
mul(Matrix4 matrix)
Postmultiplies this matrix with the given matrix, storing the result in this matrix.

Matrix4 
mulLeft(Matrix4 matrix)
Premultiplies this matrix with the given matrix, storing the result in this matrix.

static void 
mulVec(float[] mat,
float[] vec)
Multiplies the vector with the given matrix.

static void 
mulVec(float[] mat,
float[] vecs,
int offset,
int numVecs,
int stride)
Multiplies the vectors with the given matrix.

static void 
prj(float[] mat,
float[] vec)
Multiplies the vector with the given matrix, performing a division by w.

static void 
prj(float[] mat,
float[] vecs,
int offset,
int numVecs,
int stride)
Multiplies the vectors with the given matrix, , performing a division by w.

static void 
rot(float[] mat,
float[] vec)
Multiplies the vector with the top most 3x3 submatrix of the given matrix.

static void 
rot(float[] mat,
float[] vecs,
int offset,
int numVecs,
int stride)
Multiplies the vectors with the top most 3x3 submatrix of the given matrix.

Matrix4 
rotate(float axisX,
float axisY,
float axisZ,
float degrees)
Postmultiplies this matrix with a (counterclockwise) rotation matrix.

Matrix4 
rotate(Quaternion rotation)
Postmultiplies this matrix with a (counterclockwise) rotation matrix.

Matrix4 
rotate(Vector3 axis,
float degrees)
Postmultiplies this matrix with a (counterclockwise) rotation matrix.

Matrix4 
rotate(Vector3 v1,
Vector3 v2)
Postmultiplies this matrix by the rotation between two vectors.

Matrix4 
rotateRad(float axisX,
float axisY,
float axisZ,
float radians)
Postmultiplies this matrix with a (counterclockwise) rotation matrix.

Matrix4 
rotateRad(Vector3 axis,
float radians)
Postmultiplies this matrix with a (counterclockwise) rotation matrix.

Matrix4 
scale(float scaleX,
float scaleY,
float scaleZ)
Postmultiplies this matrix with a scale matrix.

Matrix4 
scl(float scale) 
Matrix4 
scl(float x,
float y,
float z) 
Matrix4 
scl(Vector3 scale) 
Matrix4 
set(Affine2 affine)
Sets this matrix to the given affine matrix.

Matrix4 
set(float[] values)
Sets the matrix to the given matrix as a float array.

Matrix4 
set(float quaternionX,
float quaternionY,
float quaternionZ,
float quaternionW)
Sets the matrix to a rotation matrix representing the quaternion.

Matrix4 
set(float translationX,
float translationY,
float translationZ,
float quaternionX,
float quaternionY,
float quaternionZ,
float quaternionW)
Sets the matrix to a rotation matrix representing the translation and quaternion.

Matrix4 
set(float translationX,
float translationY,
float translationZ,
float quaternionX,
float quaternionY,
float quaternionZ,
float quaternionW,
float scaleX,
float scaleY,
float scaleZ)
Sets the matrix to a rotation matrix representing the translation and quaternion.

Matrix4 
set(Matrix3 mat)
Sets this matrix to the given 3x3 matrix.

Matrix4 
set(Matrix4 matrix)
Sets the matrix to the given matrix.

Matrix4 
set(Quaternion quaternion)
Sets the matrix to a rotation matrix representing the quaternion.

Matrix4 
set(Vector3 position,
Quaternion orientation)
Set this matrix to the specified translation and rotation.

Matrix4 
set(Vector3 position,
Quaternion orientation,
Vector3 scale)
Set this matrix to the specified translation, rotation and scale.

Matrix4 
set(Vector3 xAxis,
Vector3 yAxis,
Vector3 zAxis,
Vector3 pos)
Sets the four columns of the matrix which correspond to the x, y and zaxis of the vector space this matrix creates as
well as the 4th column representing the translation of any point that is multiplied by this matrix.

Matrix4 
setAsAffine(Affine2 affine)
Assumes that this matrix is a 2D affine transformation, copying only the relevant components.

Matrix4 
setAsAffine(Matrix4 mat)
Assumes that both matrices are 2D affine transformations, copying only the relevant components.

Matrix4 
setFromEulerAngles(float yaw,
float pitch,
float roll)
Sets this matrix to a rotation matrix from the given euler angles.

Matrix4 
setFromEulerAnglesRad(float yaw,
float pitch,
float roll)
Sets this matrix to a rotation matrix from the given euler angles.

Matrix4 
setToLookAt(Vector3 direction,
Vector3 up)
Sets the matrix to a look at matrix with a direction and an up vector.

Matrix4 
setToLookAt(Vector3 position,
Vector3 target,
Vector3 up)
Sets this matrix to a look at matrix with the given position, target and up vector.

Matrix4 
setToOrtho(float left,
float right,
float bottom,
float top,
float near,
float far)
Sets the matrix to an orthographic projection like glOrtho (http://www.opengl.org/sdk/docs/man/xhtml/glOrtho.xml) following
the OpenGL equivalent

Matrix4 
setToOrtho2D(float x,
float y,
float width,
float height)
Sets this matrix to an orthographic projection matrix with the origin at (x,y) extending by width and height.

Matrix4 
setToOrtho2D(float x,
float y,
float width,
float height,
float near,
float far)
Sets this matrix to an orthographic projection matrix with the origin at (x,y) extending by width and height, having a near
and far plane.

Matrix4 
setToProjection(float near,
float far,
float fovy,
float aspectRatio)
Sets the matrix to a projection matrix with a near and far plane, a field of view in degrees and an aspect ratio.

Matrix4 
setToProjection(float left,
float right,
float bottom,
float top,
float near,
float far)
Sets the matrix to a projection matrix with a near/far plane, and left, bottom, right and top specifying the points on the
near plane that are mapped to the lower left and upper right corners of the viewport.

Matrix4 
setToRotation(float axisX,
float axisY,
float axisZ,
float degrees)
Sets the matrix to a rotation matrix around the given axis.

Matrix4 
setToRotation(float x1,
float y1,
float z1,
float x2,
float y2,
float z2)
Set the matrix to a rotation matrix between two vectors.

Matrix4 
setToRotation(Vector3 axis,
float degrees)
Sets the matrix to a rotation matrix around the given axis.

Matrix4 
setToRotation(Vector3 v1,
Vector3 v2)
Set the matrix to a rotation matrix between two vectors.

Matrix4 
setToRotationRad(float axisX,
float axisY,
float axisZ,
float radians)
Sets the matrix to a rotation matrix around the given axis.

Matrix4 
setToRotationRad(Vector3 axis,
float radians)
Sets the matrix to a rotation matrix around the given axis.

Matrix4 
setToScaling(float x,
float y,
float z)
Sets this matrix to a scaling matrix

Matrix4 
setToScaling(Vector3 vector)
Sets this matrix to a scaling matrix

Matrix4 
setToTranslation(float x,
float y,
float z)
Sets this matrix to a translation matrix, overwriting it first by an identity matrix and then setting the 4th column to the
translation vector.

Matrix4 
setToTranslation(Vector3 vector)
Sets this matrix to a translation matrix, overwriting it first by an identity matrix and then setting the 4th column to the
translation vector.

Matrix4 
setToTranslationAndScaling(float translationX,
float translationY,
float translationZ,
float scalingX,
float scalingY,
float scalingZ)
Sets this matrix to a translation and scaling matrix by first overwriting it with an identity and then setting the
translation vector in the 4th column and the scaling vector in the diagonal.

Matrix4 
setToTranslationAndScaling(Vector3 translation,
Vector3 scaling)
Sets this matrix to a translation and scaling matrix by first overwriting it with an identity and then setting the
translation vector in the 4th column and the scaling vector in the diagonal.

Matrix4 
setToWorld(Vector3 position,
Vector3 forward,
Vector3 up) 
Matrix4 
setTranslation(float x,
float y,
float z)
Sets the 4th column to the translation vector.

Matrix4 
setTranslation(Vector3 vector)
Sets the 4th column to the translation vector.

Matrix4 
toNormalMatrix()
removes the translational part and transposes the matrix.

java.lang.String 
toString() 
Matrix4 
tra()
Transposes the matrix.

Matrix4 
translate(float x,
float y,
float z)
Postmultiplies this matrix by a translation matrix.

Matrix4 
translate(Vector3 translation)
Postmultiplies this matrix by a translation matrix.

Matrix4 
trn(float x,
float y,
float z)
Adds a translational component to the matrix in the 4th column.

Matrix4 
trn(Vector3 vector)
Adds a translational component to the matrix in the 4th column.

public static final int M00
public static final int M01
public static final int M02
public static final int M03
public static final int M10
public static final int M11
public static final int M12
public static final int M13
public static final int M20
public static final int M21
public static final int M22
public static final int M23
public static final int M30
public static final int M31
public static final int M32
public static final int M33
public final float[] val
public Matrix4()
public Matrix4(Matrix4 matrix)
matrix
 The matrix to copy. (This matrix is not modified)public Matrix4(float[] values)
values
 The float array to copy. Remember that this matrix is in column major order. (The float array is not modified)public Matrix4(Quaternion quaternion)
Quaternion
.quaternion
 The quaternion to be copied. (The quaternion is not modified)public Matrix4(Vector3 position, Quaternion rotation, Vector3 scale)
position
 The translationrotation
 The rotation, must be normalizedscale
 The scalepublic Matrix4 set(Matrix4 matrix)
matrix
 The matrix that is to be copied. (The given matrix is not modified)public Matrix4 set(float[] values)
values
 The matrix, in float form, that is to be copied. Remember that this matrix is in column major order.public Matrix4 set(Quaternion quaternion)
quaternion
 The quaternion that is to be used to set this matrix.public Matrix4 set(float quaternionX, float quaternionY, float quaternionZ, float quaternionW)
quaternionX
 The X component of the quaternion that is to be used to set this matrix.quaternionY
 The Y component of the quaternion that is to be used to set this matrix.quaternionZ
 The Z component of the quaternion that is to be used to set this matrix.quaternionW
 The W component of the quaternion that is to be used to set this matrix.public Matrix4 set(Vector3 position, Quaternion orientation)
position
 The translationorientation
 The rotation, must be normalizedpublic Matrix4 set(float translationX, float translationY, float translationZ, float quaternionX, float quaternionY, float quaternionZ, float quaternionW)
translationX
 The X component of the translation that is to be used to set this matrix.translationY
 The Y component of the translation that is to be used to set this matrix.translationZ
 The Z component of the translation that is to be used to set this matrix.quaternionX
 The X component of the quaternion that is to be used to set this matrix.quaternionY
 The Y component of the quaternion that is to be used to set this matrix.quaternionZ
 The Z component of the quaternion that is to be used to set this matrix.quaternionW
 The W component of the quaternion that is to be used to set this matrix.public Matrix4 set(Vector3 position, Quaternion orientation, Vector3 scale)
position
 The translationorientation
 The rotation, must be normalizedscale
 The scalepublic Matrix4 set(float translationX, float translationY, float translationZ, float quaternionX, float quaternionY, float quaternionZ, float quaternionW, float scaleX, float scaleY, float scaleZ)
translationX
 The X component of the translation that is to be used to set this matrix.translationY
 The Y component of the translation that is to be used to set this matrix.translationZ
 The Z component of the translation that is to be used to set this matrix.quaternionX
 The X component of the quaternion that is to be used to set this matrix.quaternionY
 The Y component of the quaternion that is to be used to set this matrix.quaternionZ
 The Z component of the quaternion that is to be used to set this matrix.quaternionW
 The W component of the quaternion that is to be used to set this matrix.scaleX
 The X component of the scaling that is to be used to set this matrix.scaleY
 The Y component of the scaling that is to be used to set this matrix.scaleZ
 The Z component of the scaling that is to be used to set this matrix.public Matrix4 set(Vector3 xAxis, Vector3 yAxis, Vector3 zAxis, Vector3 pos)
xAxis
 The xaxis.yAxis
 The yaxis.zAxis
 The zaxis.pos
 The translation vector.public Matrix4 cpy()
public Matrix4 trn(Vector3 vector)
vector
 The translation vector to add to the current matrix. (This vector is not modified)public Matrix4 trn(float x, float y, float z)
x
 The xcomponent of the translation vector.y
 The ycomponent of the translation vector.z
 The zcomponent of the translation vector.public float[] getValues()
public Matrix4 mul(Matrix4 matrix)
A.mul(B) results in A := AB.
matrix
 The other matrix to multiply by.public Matrix4 mulLeft(Matrix4 matrix)
A.mulLeft(B) results in A := BA.
matrix
 The other matrix to multiply by.public Matrix4 tra()
public Matrix4 idt()
public Matrix4 inv()
java.lang.RuntimeException
 if the matrix is singular (not invertible)public float det()
public float det3x3()
public Matrix4 setToProjection(float near, float far, float fovy, float aspectRatio)
near
 The near planefar
 The far planefovy
 The field of view of the height in degreesaspectRatio
 The "width over height" aspect ratiopublic Matrix4 setToProjection(float left, float right, float bottom, float top, float near, float far)
left
 right
 bottom
 top
 near
 The near planefar
 The far planepublic Matrix4 setToOrtho2D(float x, float y, float width, float height)
x
 The xcoordinate of the originy
 The ycoordinate of the originwidth
 The widthheight
 The heightpublic Matrix4 setToOrtho2D(float x, float y, float width, float height, float near, float far)
x
 The xcoordinate of the originy
 The ycoordinate of the originwidth
 The widthheight
 The heightnear
 The near planefar
 The far planepublic Matrix4 setToOrtho(float left, float right, float bottom, float top, float near, float far)
left
 The left clipping planeright
 The right clipping planebottom
 The bottom clipping planetop
 The top clipping planenear
 The near clipping planefar
 The far clipping planepublic Matrix4 setTranslation(Vector3 vector)
vector
 The translation vectorpublic Matrix4 setTranslation(float x, float y, float z)
x
 The X coordinate of the translation vectory
 The Y coordinate of the translation vectorz
 The Z coordinate of the translation vectorpublic Matrix4 setToTranslation(Vector3 vector)
vector
 The translation vectorpublic Matrix4 setToTranslation(float x, float y, float z)
x
 The xcomponent of the translation vector.y
 The ycomponent of the translation vector.z
 The zcomponent of the translation vector.public Matrix4 setToTranslationAndScaling(Vector3 translation, Vector3 scaling)
translation
 The translation vectorscaling
 The scaling vectorpublic Matrix4 setToTranslationAndScaling(float translationX, float translationY, float translationZ, float scalingX, float scalingY, float scalingZ)
translationX
 The xcomponent of the translation vectortranslationY
 The ycomponent of the translation vectortranslationZ
 The zcomponent of the translation vectorscalingX
 The xcomponent of the scaling vectorscalingY
 The xcomponent of the scaling vectorscalingZ
 The xcomponent of the scaling vectorpublic Matrix4 setToRotation(Vector3 axis, float degrees)
axis
 The axisdegrees
 The angle in degreespublic Matrix4 setToRotationRad(Vector3 axis, float radians)
axis
 The axisradians
 The angle in radianspublic Matrix4 setToRotation(float axisX, float axisY, float axisZ, float degrees)
axisX
 The xcomponent of the axisaxisY
 The ycomponent of the axisaxisZ
 The zcomponent of the axisdegrees
 The angle in degreespublic Matrix4 setToRotationRad(float axisX, float axisY, float axisZ, float radians)
axisX
 The xcomponent of the axisaxisY
 The ycomponent of the axisaxisZ
 The zcomponent of the axisradians
 The angle in radianspublic Matrix4 setToRotation(Vector3 v1, Vector3 v2)
v1
 The base vectorv2
 The target vectorpublic Matrix4 setToRotation(float x1, float y1, float z1, float x2, float y2, float z2)
x1
 The base vectors x valuey1
 The base vectors y valuez1
 The base vectors z valuex2
 The target vector x valuey2
 The target vector y valuez2
 The target vector z valuepublic Matrix4 setFromEulerAngles(float yaw, float pitch, float roll)
yaw
 the yaw in degreespitch
 the pitch in degreesroll
 the roll in degreespublic Matrix4 setFromEulerAnglesRad(float yaw, float pitch, float roll)
yaw
 the yaw in radianspitch
 the pitch in radiansroll
 the roll in radianspublic Matrix4 setToScaling(Vector3 vector)
vector
 The scaling vectorpublic Matrix4 setToScaling(float x, float y, float z)
x
 The xcomponent of the scaling vectory
 The ycomponent of the scaling vectorz
 The zcomponent of the scaling vectorpublic Matrix4 setToLookAt(Vector3 direction, Vector3 up)
direction
 The direction vectorup
 The up vectorpublic Matrix4 setToLookAt(Vector3 position, Vector3 target, Vector3 up)
position
 the positiontarget
 the targetup
 the up vectorpublic java.lang.String toString()
toString
in class java.lang.Object
public Matrix4 lerp(Matrix4 matrix, float alpha)
matrix
 the matrixalpha
 the alpha value in the range [0,1]public Matrix4 avg(Matrix4 other, float w)
other
 The other transformw
 Weight of this transform; weight of the other transform is (1  w)public Matrix4 avg(Matrix4[] t)
t
 List of transformspublic Matrix4 avg(Matrix4[] t, float[] w)
t
 List of transformsw
 List of weightspublic Matrix4 set(Matrix3 mat)
mat
 the matrixpublic Matrix4 set(Affine2 affine)
[ M00 M01 0 M02 ] [ M10 M11 0 M12 ] [ 0 0 1 0 ] [ 0 0 0 1 ]
affine
 the affine matrixpublic Matrix4 setAsAffine(Affine2 affine)
[ M00 M01 _ M02 ] [ M10 M11 _ M12 ] [ _ _ _ _ ] [ _ _ _ _ ]
affine
 the source matrixpublic Matrix4 setAsAffine(Matrix4 mat)
[ M00 M01 _ M03 ] [ M10 M11 _ M13 ] [ _ _ _ _ ] [ _ _ _ _ ]
mat
 the source matrixpublic Matrix4 scl(float x, float y, float z)
public Matrix4 scl(float scale)
public Quaternion getRotation(Quaternion rotation, boolean normalizeAxes)
rotation
 The Quaternion
to receive the rotationnormalizeAxes
 True to normalize the axes, necessary when the matrix might also include scaling.Quaternion
for chaining.public Quaternion getRotation(Quaternion rotation)
rotation
 The Quaternion
to receive the rotationQuaternion
for chaining.public float getScaleXSquared()
public float getScaleYSquared()
public float getScaleZSquared()
public float getScaleX()
public float getScaleY()
public float getScaleZ()
public Vector3 getScale(Vector3 scale)
scale
 The vector which will receive the (nonnegative) scale components on each axis.public Matrix4 toNormalMatrix()
public static void mul(float[] mata, float[] matb)
val
. This is the same as mul(Matrix4)
.mata
 the first matrix.matb
 the second matrix.public static void mulVec(float[] mat, float[] vec)
val
. The vector array is assumed to hold a 3component vector, with x being the first element, y being
the second and z being the last component. The result is stored in the vector array. This is the same as
Vector3.mul(Matrix4)
.mat
 the matrixvec
 the vector.public static void mulVec(float[] mat, float[] vecs, int offset, int numVecs, int stride)
val
. The vectors array is assumed to hold 3component vectors. Offset specifies the offset into the
array where the xcomponent of the first vector is located. The numVecs parameter specifies the number of vectors stored in
the vectors array. The stride parameter specifies the number of floats between subsequent vectors and must be >= 3. This is
the same as Vector3.mul(Matrix4)
applied to multiple vectors.mat
 the matrixvecs
 the vectorsoffset
 the offset into the vectors arraynumVecs
 the number of vectorsstride
 the stride between vectors in floatspublic static void prj(float[] mat, float[] vec)
val
. The vector array is assumed to hold a 3component vector, with x being
the first element, y being the second and z being the last component. The result is stored in the vector array. This is the
same as Vector3.prj(Matrix4)
.mat
 the matrixvec
 the vector.public static void prj(float[] mat, float[] vecs, int offset, int numVecs, int stride)
val
. The vectors array is assumed to hold 3component vectors. Offset
specifies the offset into the array where the xcomponent of the first vector is located. The numVecs parameter specifies
the number of vectors stored in the vectors array. The stride parameter specifies the number of floats between subsequent
vectors and must be >= 3. This is the same as Vector3.prj(Matrix4)
applied to multiple vectors.mat
 the matrixvecs
 the vectorsoffset
 the offset into the vectors arraynumVecs
 the number of vectorsstride
 the stride between vectors in floatspublic static void rot(float[] mat, float[] vec)
val
. The vector array is assumed to hold a 3component vector, with x being
the first element, y being the second and z being the last component. The result is stored in the vector array. This is the
same as Vector3.rot(Matrix4)
.mat
 the matrixvec
 the vector.public static void rot(float[] mat, float[] vecs, int offset, int numVecs, int stride)
val
. The vectors array is assumed to hold 3component vectors.
Offset specifies the offset into the array where the xcomponent of the first vector is located. The numVecs parameter
specifies the number of vectors stored in the vectors array. The stride parameter specifies the number of floats between
subsequent vectors and must be >= 3. This is the same as Vector3.rot(Matrix4)
applied to multiple vectors.mat
 the matrixvecs
 the vectorsoffset
 the offset into the vectors arraynumVecs
 the number of vectorsstride
 the stride between vectors in floatspublic static boolean inv(float[] values)
val
.values
 the matrix values.public static float det(float[] values)
val
.values
 the matrix values.public Matrix4 translate(Vector3 translation)
translation
 public Matrix4 translate(float x, float y, float z)
x
 Translation in the xaxis.y
 Translation in the yaxis.z
 Translation in the zaxis.public Matrix4 rotate(Vector3 axis, float degrees)
axis
 The vector axis to rotate around.degrees
 The angle in degrees.public Matrix4 rotateRad(Vector3 axis, float radians)
axis
 The vector axis to rotate around.radians
 The angle in radians.public Matrix4 rotate(float axisX, float axisY, float axisZ, float degrees)
axisX
 The xaxis component of the vector to rotate around.axisY
 The yaxis component of the vector to rotate around.axisZ
 The zaxis component of the vector to rotate around.degrees
 The angle in degreespublic Matrix4 rotateRad(float axisX, float axisY, float axisZ, float radians)
axisX
 The xaxis component of the vector to rotate around.axisY
 The yaxis component of the vector to rotate around.axisZ
 The zaxis component of the vector to rotate around.radians
 The angle in radianspublic Matrix4 rotate(Quaternion rotation)
rotation
 public Matrix4 rotate(Vector3 v1, Vector3 v2)
v1
 The base vectorv2
 The target vectorpublic Matrix4 scale(float scaleX, float scaleY, float scaleZ)
scaleX
 The scale in the xaxis.scaleY
 The scale in the yaxis.scaleZ
 The scale in the zaxis.public void extract4x3Matrix(float[] dst)
dst
 the destination matrixpublic boolean hasRotationOrScaling()