Uses of Class org.joml.Matrix4f (JOML 1.9.16 API)

Packages that use Matrix4f
Package Description

org.joml
Contains all classes of JOML.

org.joml.internal
Contains internal classes.

Packages that use Matrix4f
Package	Description
org.joml	Contains all classes of JOML.
org.joml.internal	Contains internal classes.

Uses of Matrix4f in org.joml

Subclasses of Matrix4f in org.joml
Modifier and Type	Class and Description
`class`	`Matrix4fStack` A stack of many `Matrix4f` instances.

Methods in org.joml that return Matrix4f
Modifier and Type	Method and Description
`Matrix4f`	Matrix4f.`_m00(float m00)` Set the value of the matrix element at column 0 and row 0 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m01(float m01)` Set the value of the matrix element at column 0 and row 1 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m02(float m02)` Set the value of the matrix element at column 0 and row 2 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m03(float m03)` Set the value of the matrix element at column 0 and row 3 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m10(float m10)` Set the value of the matrix element at column 1 and row 0 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m11(float m11)` Set the value of the matrix element at column 1 and row 1 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m12(float m12)` Set the value of the matrix element at column 1 and row 2 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m13(float m13)` Set the value of the matrix element at column 1 and row 3 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m20(float m20)` Set the value of the matrix element at column 2 and row 0 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m21(float m21)` Set the value of the matrix element at column 2 and row 1 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m22(float m22)` Set the value of the matrix element at column 2 and row 2 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m23(float m23)` Set the value of the matrix element at column 2 and row 3 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m30(float m30)` Set the value of the matrix element at column 3 and row 0 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m31(float m31)` Set the value of the matrix element at column 3 and row 1 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m32(float m32)` Set the value of the matrix element at column 3 and row 2 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`_m33(float m33)` Set the value of the matrix element at column 3 and row 3 without updating the properties of the matrix.
`Matrix4f`	Matrix4f.`add(Matrix4fc other)` Component-wise add `this` and `other`.
`Matrix4f`	Matrix4fc.`add(Matrix4fc other, Matrix4f dest)` Component-wise add `this` and `other` and store the result in `dest`.
`Matrix4f`	Matrix4f.`add(Matrix4fc other, Matrix4f dest)`
`Matrix4f`	Matrix4f.`add4x3(Matrix4fc other)` Component-wise add the upper 4x3 submatrices of `this` and `other`.
`Matrix4f`	Matrix4fc.`add4x3(Matrix4fc other, Matrix4f dest)` Component-wise add the upper 4x3 submatrices of `this` and `other` and store the result in `dest`.
`Matrix4f`	Matrix4f.`add4x3(Matrix4fc other, Matrix4f dest)`
`Matrix4f`	Matrix4f.`affineSpan(Vector3f corner, Vector3f xDir, Vector3f yDir, Vector3f zDir)` Compute the extents of the coordinate system before this `affine` transformation was applied and store the resulting corner coordinates in `corner` and the span vectors in `xDir`, `yDir` and `zDir`.
`Matrix4f`	Matrix4f.`arcball(float radius, float centerX, float centerY, float centerZ, float angleX, float angleY)` Apply an arcball view transformation to this matrix with the given `radius` and center `(centerX, centerY, centerZ)` position of the arcball and the specified X and Y rotation angles.
`Matrix4f`	Matrix4fc.`arcball(float radius, float centerX, float centerY, float centerZ, float angleX, float angleY, Matrix4f dest)` Apply an arcball view transformation to this matrix with the given `radius` and center `(centerX, centerY, centerZ)` position of the arcball and the specified X and Y rotation angles, and store the result in `dest`.
`Matrix4f`	Matrix4f.`arcball(float radius, float centerX, float centerY, float centerZ, float angleX, float angleY, Matrix4f dest)`
`Matrix4f`	Matrix4f.`arcball(float radius, Vector3fc center, float angleX, float angleY)` Apply an arcball view transformation to this matrix with the given `radius` and `center` position of the arcball and the specified X and Y rotation angles.
`Matrix4f`	Matrix4fc.`arcball(float radius, Vector3fc center, float angleX, float angleY, Matrix4f dest)` Apply an arcball view transformation to this matrix with the given `radius` and `center` position of the arcball and the specified X and Y rotation angles, and store the result in `dest`.
`Matrix4f`	Matrix4f.`arcball(float radius, Vector3fc center, float angleX, float angleY, Matrix4f dest)`
`Matrix4f`	Matrix4f.`assume(int properties)` Assume the given properties about this matrix.
`Matrix4f`	Matrix4f.`billboardCylindrical(Vector3fc objPos, Vector3fc targetPos, Vector3fc up)` Set this matrix to a cylindrical billboard transformation that rotates the local +Z axis of a given object with position `objPos` towards a target position at `targetPos` while constraining a cylindrical rotation around the given `up` vector.
`Matrix4f`	Matrix4f.`billboardSpherical(Vector3fc objPos, Vector3fc targetPos)` Set this matrix to a spherical billboard transformation that rotates the local +Z axis of a given object with position `objPos` towards a target position at `targetPos` using a shortest arc rotation by not preserving any up vector of the object.
`Matrix4f`	Matrix4f.`billboardSpherical(Vector3fc objPos, Vector3fc targetPos, Vector3fc up)` Set this matrix to a spherical billboard transformation that rotates the local +Z axis of a given object with position `objPos` towards a target position at `targetPos`.
`Matrix4f`	Matrix4f.`determineProperties()` Compute and set the matrix properties returned by `properties()` based on the current matrix element values.
`Matrix4f`	Matrix4f.`fma4x3(Matrix4fc other, float otherFactor)` Component-wise add the upper 4x3 submatrices of `this` and `other` by first multiplying each component of `other`'s 4x3 submatrix by `otherFactor` and adding that result to `this`.
`Matrix4f`	Matrix4fc.`fma4x3(Matrix4fc other, float otherFactor, Matrix4f dest)` Component-wise add the upper 4x3 submatrices of `this` and `other` by first multiplying each component of `other`'s 4x3 submatrix by `otherFactor`, adding that to `this` and storing the final result in `dest`.
`Matrix4f`	Matrix4f.`fma4x3(Matrix4fc other, float otherFactor, Matrix4f dest)`
`Matrix4f`	Matrix4f.`frustum(float left, float right, float bottom, float top, float zNear, float zFar)` Apply an arbitrary perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix.
`Matrix4f`	Matrix4f.`frustum(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne)` Apply an arbitrary perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix.
`Matrix4f`	Matrix4fc.`frustum(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`frustum(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`frustum(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`frustum(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`frustumAabb(Vector3f min, Vector3f max)` Compute the axis-aligned bounding box of the frustum described by `this` matrix and store the minimum corner coordinates in the given `min` and the maximum corner coordinates in the given `max` vector.
`Matrix4f`	Matrix4f.`frustumAabb(Vector3f min, Vector3f max)` Compute the axis-aligned bounding box of the frustum described by `this` matrix and store the minimum corner coordinates in the given `min` and the maximum corner coordinates in the given `max` vector.
`Matrix4f`	Matrix4f.`frustumLH(float left, float right, float bottom, float top, float zNear, float zFar)` Apply an arbitrary perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range to this matrix.
`Matrix4f`	Matrix4f.`frustumLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne)` Apply an arbitrary perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range to this matrix.
`Matrix4f`	Matrix4fc.`frustumLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`frustumLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`frustumLH(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`frustumLH(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`get(Matrix4f dest)` Get the current values of `this` matrix and store them into `dest`.
`Matrix4f`	Quaternionfc.`get(Matrix4f dest)` Set the given destination matrix to the rotation represented by `this`.
`Matrix4f`	AxisAngle4f.`get(Matrix4f m)` Set the given `Matrix4f` to a rotation transformation equivalent to this `AxisAngle4f`.
`Matrix4f`	Matrix4f.`get(Matrix4f dest)` Get the current values of `this` matrix and store them into `dest`.
`Matrix4f`	AxisAngle4d.`get(Matrix4f m)` Set the given `Matrix4f` to a rotation transformation equivalent to this `AxisAngle4d`.
`Matrix4f`	Matrix3f.`get(Matrix4f dest)`
`Matrix4f`	Quaterniond.`get(Matrix4f dest)`
`Matrix4f`	Matrix3fc.`get(Matrix4f dest)` Get the current values of `this` matrix and store them as the rotational component of `dest`.
`Matrix4f`	Quaterniondc.`get(Matrix4f dest)` Set the given destination matrix to the rotation represented by `this`.
`Matrix4f`	Matrix4x3fc.`get(Matrix4f dest)` Get the current values of `this` matrix and store them into the upper 4x3 submatrix of `dest`.
`Matrix4f`	Matrix4x3f.`get(Matrix4f dest)`
`Matrix4f`	Quaternionf.`get(Matrix4f dest)`
`Matrix4f`	Matrix4f.`identity()` Reset this matrix to the identity.
`Matrix4f`	Matrix4f.`invert()` Invert this matrix.
`Matrix4f`	Matrix4fc.`invert(Matrix4f dest)` Invert this matrix and write the result into `dest`.
`Matrix4f`	Matrix4f.`invert(Matrix4f dest)`
`Matrix4f`	Matrix4f.`invertAffine()` Invert this matrix by assuming that it is an `affine` transformation (i.e.
`Matrix4f`	Matrix4fc.`invertAffine(Matrix4f dest)` Invert this matrix by assuming that it is an `affine` transformation (i.e.
`Matrix4f`	Matrix4f.`invertAffine(Matrix4f dest)`
`Matrix4f`	Matrix4f.`invertFrustum()` If `this` is an arbitrary perspective projection matrix obtained via one of the `frustum()` methods or via `setFrustum()`, then this method builds the inverse of `this`.
`Matrix4f`	Matrix4fc.`invertFrustum(Matrix4f dest)` If `this` is an arbitrary perspective projection matrix obtained via one of the `frustum()` methods, then this method builds the inverse of `this` and stores it into the given `dest`.
`Matrix4f`	Matrix4f.`invertFrustum(Matrix4f dest)` If `this` is an arbitrary perspective projection matrix obtained via one of the `frustum()` methods or via `setFrustum()`, then this method builds the inverse of `this` and stores it into the given `dest`.
`Matrix4f`	Matrix4f.`invertOrtho()` Invert `this` orthographic projection matrix.
`Matrix4f`	Matrix4fc.`invertOrtho(Matrix4f dest)` Invert `this` orthographic projection matrix and store the result into the given `dest`.
`Matrix4f`	Matrix4f.`invertOrtho(Matrix4f dest)`
`Matrix4f`	Matrix4f.`invertPerspective()` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods or via `setPerspective()`, that is, if `this` is a symmetrical perspective frustum transformation, then this method builds the inverse of `this`.
`Matrix4f`	Matrix4fc.`invertPerspective(Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods, that is, if `this` is a symmetrical perspective frustum transformation, then this method builds the inverse of `this` and stores it into the given `dest`.
`Matrix4f`	Matrix4f.`invertPerspective(Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods or via `setPerspective()`, that is, if `this` is a symmetrical perspective frustum transformation, then this method builds the inverse of `this` and stores it into the given `dest`.
`Matrix4f`	Matrix4fc.`invertPerspectiveView(Matrix4fc view, Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods, that is, if `this` is a symmetrical perspective frustum transformation and the given `view` matrix is `affine` and has unit scaling (for example by being obtained via `lookAt()`), then this method builds the inverse of `this * view` and stores it into the given `dest`.
`Matrix4f`	Matrix4f.`invertPerspectiveView(Matrix4fc view, Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods or via `setPerspective()`, that is, if `this` is a symmetrical perspective frustum transformation and the given `view` matrix is `affine` and has unit scaling (for example by being obtained via `lookAt()`), then this method builds the inverse of `this * view` and stores it into the given `dest`.
`Matrix4f`	Matrix4fc.`invertPerspectiveView(Matrix4x3fc view, Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods, that is, if `this` is a symmetrical perspective frustum transformation and the given `view` matrix has unit scaling, then this method builds the inverse of `this * view` and stores it into the given `dest`.
`Matrix4f`	Matrix4f.`invertPerspectiveView(Matrix4x3fc view, Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods or via `setPerspective()`, that is, if `this` is a symmetrical perspective frustum transformation and the given `view` matrix has unit scaling, then this method builds the inverse of `this * view` and stores it into the given `dest`.
`Matrix4f`	Matrix4f.`lerp(Matrix4fc other, float t)` Linearly interpolate `this` and `other` using the given interpolation factor `t` and store the result in `this`.
`Matrix4f`	Matrix4fc.`lerp(Matrix4fc other, float t, Matrix4f dest)` Linearly interpolate `this` and `other` using the given interpolation factor `t` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lerp(Matrix4fc other, float t, Matrix4f dest)`
`Matrix4f`	Matrix4f.`lookAlong(float dirX, float dirY, float dirZ, float upX, float upY, float upZ)` Apply a rotation transformation to this matrix to make `-z` point along `dir`.
`Matrix4f`	Matrix4fc.`lookAlong(float dirX, float dirY, float dirZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a rotation transformation to this matrix to make `-z` point along `dir` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAlong(float dirX, float dirY, float dirZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a rotation transformation to this matrix to make `-z` point along `dir` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAlong(Vector3fc dir, Vector3fc up)` Apply a rotation transformation to this matrix to make `-z` point along `dir`.
`Matrix4f`	Matrix4fc.`lookAlong(Vector3fc dir, Vector3fc up, Matrix4f dest)` Apply a rotation transformation to this matrix to make `-z` point along `dir` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAlong(Vector3fc dir, Vector3fc up, Matrix4f dest)` Apply a rotation transformation to this matrix to make `-z` point along `dir` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAt(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye`.
`Matrix4f`	Matrix4fc.`lookAt(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAt(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAt(Vector3fc eye, Vector3fc center, Vector3fc up)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye`.
`Matrix4f`	Matrix4fc.`lookAt(Vector3fc eye, Vector3fc center, Vector3fc up, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAt(Vector3fc eye, Vector3fc center, Vector3fc up, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAtLH(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye`.
`Matrix4f`	Matrix4fc.`lookAtLH(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAtLH(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAtLH(Vector3fc eye, Vector3fc center, Vector3fc up)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye`.
`Matrix4f`	Matrix4fc.`lookAtLH(Vector3fc eye, Vector3fc center, Vector3fc up, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAtLH(Vector3fc eye, Vector3fc center, Vector3fc up, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`lookAtPerspective(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAtPerspective(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`lookAtPerspectiveLH(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAtPerspectiveLH(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`m00(float m00)` Set the value of the matrix element at column 0 and row 0.
`Matrix4f`	Matrix4f.`m01(float m01)` Set the value of the matrix element at column 0 and row 1.
`Matrix4f`	Matrix4f.`m02(float m02)` Set the value of the matrix element at column 0 and row 2.
`Matrix4f`	Matrix4f.`m03(float m03)` Set the value of the matrix element at column 0 and row 3.
`Matrix4f`	Matrix4f.`m10(float m10)` Set the value of the matrix element at column 1 and row 0.
`Matrix4f`	Matrix4f.`m11(float m11)` Set the value of the matrix element at column 1 and row 1.
`Matrix4f`	Matrix4f.`m12(float m12)` Set the value of the matrix element at column 1 and row 2.
`Matrix4f`	Matrix4f.`m13(float m13)` Set the value of the matrix element at column 1 and row 3.
`Matrix4f`	Matrix4f.`m20(float m20)` Set the value of the matrix element at column 2 and row 0.
`Matrix4f`	Matrix4f.`m21(float m21)` Set the value of the matrix element at column 2 and row 1.
`Matrix4f`	Matrix4f.`m22(float m22)` Set the value of the matrix element at column 2 and row 2.
`Matrix4f`	Matrix4f.`m23(float m23)` Set the value of the matrix element at column 2 and row 3.
`Matrix4f`	Matrix4f.`m30(float m30)` Set the value of the matrix element at column 3 and row 0.
`Matrix4f`	Matrix4f.`m31(float m31)` Set the value of the matrix element at column 3 and row 1.
`Matrix4f`	Matrix4f.`m32(float m32)` Set the value of the matrix element at column 3 and row 2.
`Matrix4f`	Matrix4f.`m33(float m33)` Set the value of the matrix element at column 3 and row 3.
`Matrix4f`	Matrix4f.`mul(Matrix3x2fc right)` Multiply this matrix by the supplied `right` matrix and store the result in `this`.
`Matrix4f`	Matrix4fc.`mul(Matrix3x2fc right, Matrix4f dest)` Multiply this matrix by the supplied `right` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mul(Matrix3x2fc right, Matrix4f dest)`
`Matrix4f`	Matrix4f.`mul(Matrix4fc right)` Multiply this matrix by the supplied `right` matrix and store the result in `this`.
`Matrix4f`	Matrix4fc.`mul(Matrix4fc right, Matrix4f dest)` Multiply this matrix by the supplied `right` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mul(Matrix4fc right, Matrix4f dest)`
`Matrix4f`	Matrix4f.`mul(Matrix4x3fc right)` Multiply this matrix by the supplied `right` matrix and store the result in `this`.
`Matrix4f`	Matrix4fc.`mul(Matrix4x3fc right, Matrix4f dest)` Multiply this matrix by the supplied `right` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mul(Matrix4x3fc right, Matrix4f dest)`
`Matrix4f`	Matrix4f.`mul4x3ComponentWise(Matrix4fc other)` Component-wise multiply the upper 4x3 submatrices of `this` by `other`.
`Matrix4f`	Matrix4fc.`mul4x3ComponentWise(Matrix4fc other, Matrix4f dest)` Component-wise multiply the upper 4x3 submatrices of `this` by `other` and store the result in `dest`.
`Matrix4f`	Matrix4f.`mul4x3ComponentWise(Matrix4fc other, Matrix4f dest)`
`Matrix4f`	Matrix4f.`mulAffine(Matrix4fc right)` Multiply this matrix by the supplied `right` matrix, both of which are assumed to be `affine`, and store the result in `this`.
`Matrix4f`	Matrix4fc.`mulAffine(Matrix4fc right, Matrix4f dest)` Multiply this matrix by the supplied `right` matrix, both of which are assumed to be `affine`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulAffine(Matrix4fc right, Matrix4f dest)`
`Matrix4f`	Matrix4f.`mulAffineR(Matrix4fc right)` Multiply this matrix by the supplied `right` matrix, which is assumed to be `affine`, and store the result in `this`.
`Matrix4f`	Matrix4fc.`mulAffineR(Matrix4fc right, Matrix4f dest)` Multiply this matrix by the supplied `right` matrix, which is assumed to be `affine`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulAffineR(Matrix4fc right, Matrix4f dest)`
`Matrix4f`	Matrix4f.`mulComponentWise(Matrix4fc other)` Component-wise multiply `this` by `other`.
`Matrix4f`	Matrix4fc.`mulComponentWise(Matrix4fc other, Matrix4f dest)` Component-wise multiply `this` by `other` and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulComponentWise(Matrix4fc other, Matrix4f dest)`
`Matrix4f`	Matrix4f.`mulLocal(Matrix4fc left)` Pre-multiply this matrix by the supplied `left` matrix and store the result in `this`.
`Matrix4f`	Matrix4fc.`mulLocal(Matrix4fc left, Matrix4f dest)` Pre-multiply this matrix by the supplied `left` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulLocal(Matrix4fc left, Matrix4f dest)`
`Matrix4f`	Matrix4f.`mulLocalAffine(Matrix4fc left)` Pre-multiply this matrix by the supplied `left` matrix, both of which are assumed to be `affine`, and store the result in `this`.
`Matrix4f`	Matrix4fc.`mulLocalAffine(Matrix4fc left, Matrix4f dest)` Pre-multiply this matrix by the supplied `left` matrix, both of which are assumed to be `affine`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulLocalAffine(Matrix4fc left, Matrix4f dest)`
`Matrix4f`	Matrix4f.`mulOrthoAffine(Matrix4fc view)` Multiply `this` orthographic projection matrix by the supplied `affine` `view` matrix.
`Matrix4f`	Matrix4fc.`mulOrthoAffine(Matrix4fc view, Matrix4f dest)` Multiply `this` orthographic projection matrix by the supplied `affine` `view` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulOrthoAffine(Matrix4fc view, Matrix4f dest)`
`Matrix4f`	Matrix4f.`mulPerspectiveAffine(Matrix4fc view)` Multiply `this` symmetric perspective projection matrix by the supplied `affine` `view` matrix.
`Matrix4f`	Matrix4fc.`mulPerspectiveAffine(Matrix4fc view, Matrix4f dest)` Multiply `this` symmetric perspective projection matrix by the supplied `affine` `view` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulPerspectiveAffine(Matrix4fc view, Matrix4f dest)`
`Matrix4f`	Matrix4f.`mulPerspectiveAffine(Matrix4x3fc view)` Multiply `this` symmetric perspective projection matrix by the supplied `view` matrix.
`Matrix4f`	Matrix4fc.`mulPerspectiveAffine(Matrix4x3fc view, Matrix4f dest)` Multiply `this` symmetric perspective projection matrix by the supplied `view` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulPerspectiveAffine(Matrix4x3fc view, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mulTranslationAffine(Matrix4fc right, Matrix4f dest)` Multiply this matrix, which is assumed to only contain a translation, by the supplied `right` matrix, which is assumed to be `affine`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulTranslationAffine(Matrix4fc right, Matrix4f dest)`
`Matrix4f`	Matrix4f.`normal()` Compute a normal matrix from the upper left 3x3 submatrix of `this` and store it into the upper left 3x3 submatrix of `this`.
`Matrix4f`	Matrix4fc.`normal(Matrix4f dest)` Compute a normal matrix from the upper left 3x3 submatrix of `this` and store it into the upper left 3x3 submatrix of `dest`.
`Matrix4f`	Matrix4f.`normal(Matrix4f dest)` Compute a normal matrix from the upper left 3x3 submatrix of `this` and store it into the upper left 3x3 submatrix of `dest`.
`Matrix4f`	Matrix4f.`normalize3x3()` Normalize the upper left 3x3 submatrix of this matrix.
`Matrix4f`	Matrix4fc.`normalize3x3(Matrix4f dest)` Normalize the upper left 3x3 submatrix of this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`normalize3x3(Matrix4f dest)`
`Matrix4f`	Matrix4f.`obliqueZ(float a, float b)` Apply an oblique projection transformation to this matrix with the given values for `a` and `b`.
`Matrix4f`	Matrix4fc.`obliqueZ(float a, float b, Matrix4f dest)` Apply an oblique projection transformation to this matrix with the given values for `a` and `b` and store the result in `dest`.
`Matrix4f`	Matrix4f.`obliqueZ(float a, float b, Matrix4f dest)` Apply an oblique projection transformation to this matrix with the given values for `a` and `b` and store the result in `dest`.
`Matrix4f`	Matrix4f.`ortho(float left, float right, float bottom, float top, float zNear, float zFar)` Apply an orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix.
`Matrix4f`	Matrix4f.`ortho(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne)` Apply an orthographic projection transformation for a right-handed coordinate system using the given NDC z range to this matrix.
`Matrix4f`	Matrix4fc.`ortho(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`ortho(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`ortho(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`ortho(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`ortho2D(float left, float right, float bottom, float top)` Apply an orthographic projection transformation for a right-handed coordinate system to this matrix.
`Matrix4f`	Matrix4fc.`ortho2D(float left, float right, float bottom, float top, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`ortho2D(float left, float right, float bottom, float top, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`ortho2DLH(float left, float right, float bottom, float top)` Apply an orthographic projection transformation for a left-handed coordinate system to this matrix.
`Matrix4f`	Matrix4fc.`ortho2DLH(float left, float right, float bottom, float top, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordinate system to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`ortho2DLH(float left, float right, float bottom, float top, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordinate system to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`orthoCrop(Matrix4fc view, Matrix4f dest)` Build an ortographic projection transformation that fits the view-projection transformation represented by `this` into the given affine `view` transformation.
`Matrix4f`	Matrix4f.`orthoCrop(Matrix4fc view, Matrix4f dest)` Build an ortographic projection transformation that fits the view-projection transformation represented by `this` into the given affine `view` transformation.
`Matrix4f`	Matrix4f.`orthoLH(float left, float right, float bottom, float top, float zNear, float zFar)` Apply an orthographic projection transformation for a left-handed coordiante system using OpenGL's NDC z range of `[-1..+1]` to this matrix.
`Matrix4f`	Matrix4f.`orthoLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne)` Apply an orthographic projection transformation for a left-handed coordiante system using the given NDC z range to this matrix.
`Matrix4f`	Matrix4fc.`orthoLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordiante system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordiante system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`orthoLH(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordiante system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoLH(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordiante system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoSymmetric(float width, float height, float zNear, float zFar)` Apply a symmetric orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix.
`Matrix4f`	Matrix4f.`orthoSymmetric(float width, float height, float zNear, float zFar, boolean zZeroToOne)` Apply a symmetric orthographic projection transformation for a right-handed coordinate system using the given NDC z range to this matrix.
`Matrix4f`	Matrix4fc.`orthoSymmetric(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoSymmetric(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`orthoSymmetric(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoSymmetric(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoSymmetricLH(float width, float height, float zNear, float zFar)` Apply a symmetric orthographic projection transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix.
`Matrix4f`	Matrix4f.`orthoSymmetricLH(float width, float height, float zNear, float zFar, boolean zZeroToOne)` Apply a symmetric orthographic projection transformation for a left-handed coordinate system using the given NDC z range to this matrix.
`Matrix4f`	Matrix4fc.`orthoSymmetricLH(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoSymmetricLH(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`orthoSymmetricLH(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoSymmetricLH(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspective(float fovy, float aspect, float zNear, float zFar)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix.
`Matrix4f`	Matrix4f.`perspective(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne)` Apply a symmetric perspective projection frustum transformation using for a right-handed coordinate system the given NDC z range to this matrix.
`Matrix4f`	Matrix4fc.`perspective(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspective(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspective(float fovy, float aspect, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspective(float fovy, float aspect, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveFrustumSlice(float near, float far, Matrix4f dest)` Change the near and far clip plane distances of `this` perspective frustum transformation matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveFrustumSlice(float near, float far, Matrix4f dest)` Change the near and far clip plane distances of `this` perspective frustum transformation matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveLH(float fovy, float aspect, float zNear, float zFar)` Apply a symmetric perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix.
`Matrix4f`	Matrix4f.`perspectiveLH(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne)` Apply a symmetric perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range to this matrix.
`Matrix4f`	Matrix4fc.`perspectiveLH(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveLH(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveLH(float fovy, float aspect, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveLH(float fovy, float aspect, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar)` Apply an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix.
`Matrix4f`	Matrix4f.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar)` Apply an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix.
`Matrix4f`	Matrix4fc.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar, boolean zZeroToOne)` Apply an asymmetric off-center perspective projection frustum transformation using for a right-handed coordinate system the given NDC z range to this matrix.
`Matrix4f`	Matrix4f.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar, boolean zZeroToOne)` Apply an asymmetric off-center perspective projection frustum transformation using for a right-handed coordinate system the given NDC z range to this matrix.
`Matrix4f`	Matrix4fc.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar, Matrix4f dest)` Apply an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar, Matrix4f dest)` Apply an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveRect(float width, float height, float zNear, float zFar)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix.
`Matrix4f`	Matrix4f.`perspectiveRect(float width, float height, float zNear, float zFar)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix.
`Matrix4f`	Matrix4fc.`perspectiveRect(float width, float height, float zNear, float zFar, boolean zZeroToOne)` Apply a symmetric perspective projection frustum transformation using for a right-handed coordinate system the given NDC z range to this matrix.
`Matrix4f`	Matrix4f.`perspectiveRect(float width, float height, float zNear, float zFar, boolean zZeroToOne)` Apply a symmetric perspective projection frustum transformation using for a right-handed coordinate system the given NDC z range to this matrix.
`Matrix4f`	Matrix4fc.`perspectiveRect(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveRect(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveRect(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveRect(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`pick(float x, float y, float width, float height, int[] viewport)` Apply a picking transformation to this matrix using the given window coordinates `(x, y)` as the pick center and the given `(width, height)` as the size of the picking region in window coordinates.
`Matrix4f`	Matrix4fc.`pick(float x, float y, float width, float height, int[] viewport, Matrix4f dest)` Apply a picking transformation to this matrix using the given window coordinates `(x, y)` as the pick center and the given `(width, height)` as the size of the picking region in window coordinates, and store the result in `dest`.
`Matrix4f`	Matrix4f.`pick(float x, float y, float width, float height, int[] viewport, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`projectedGridRange(Matrix4fc projector, float sLower, float sUpper, Matrix4f dest)` Compute the range matrix for the Projected Grid transformation as described in chapter "2.4.2 Creating the range conversion matrix" of the paper Real-time water rendering - Introducing the projected grid concept based on the inverse of the view-projection matrix which is assumed to be `this`, and store that range matrix into `dest`.
`Matrix4f`	Matrix4f.`projectedGridRange(Matrix4fc projector, float sLower, float sUpper, Matrix4f dest)`
`Matrix4f`	Matrix4f.`reflect(float a, float b, float c, float d)` Apply a mirror/reflection transformation to this matrix that reflects about the given plane specified via the equation `xa + yb + z*c + d = 0`.
`Matrix4f`	Matrix4f.`reflect(float nx, float ny, float nz, float px, float py, float pz)` Apply a mirror/reflection transformation to this matrix that reflects about the given plane specified via the plane normal and a point on the plane.
`Matrix4f`	Matrix4fc.`reflect(float nx, float ny, float nz, float px, float py, float pz, Matrix4f dest)` Apply a mirror/reflection transformation to this matrix that reflects about the given plane specified via the plane normal and a point on the plane, and store the result in `dest`.
`Matrix4f`	Matrix4f.`reflect(float nx, float ny, float nz, float px, float py, float pz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`reflect(float a, float b, float c, float d, Matrix4f dest)` Apply a mirror/reflection transformation to this matrix that reflects about the given plane specified via the equation `xa + yb + z*c + d = 0` and store the result in `dest`.
`Matrix4f`	Matrix4f.`reflect(float a, float b, float c, float d, Matrix4f dest)`
`Matrix4f`	Matrix4f.`reflect(Quaternionfc orientation, Vector3fc point)` Apply a mirror/reflection transformation to this matrix that reflects about a plane specified via the plane orientation and a point on the plane.
`Matrix4f`	Matrix4fc.`reflect(Quaternionfc orientation, Vector3fc point, Matrix4f dest)` Apply a mirror/reflection transformation to this matrix that reflects about a plane specified via the plane orientation and a point on the plane, and store the result in `dest`.
`Matrix4f`	Matrix4f.`reflect(Quaternionfc orientation, Vector3fc point, Matrix4f dest)`
`Matrix4f`	Matrix4f.`reflect(Vector3fc normal, Vector3fc point)` Apply a mirror/reflection transformation to this matrix that reflects about the given plane specified via the plane normal and a point on the plane.
`Matrix4f`	Matrix4fc.`reflect(Vector3fc normal, Vector3fc point, Matrix4f dest)` Apply a mirror/reflection transformation to this matrix that reflects about the given plane specified via the plane normal and a point on the plane, and store the result in `dest`.
`Matrix4f`	Matrix4f.`reflect(Vector3fc normal, Vector3fc point, Matrix4f dest)`
`Matrix4f`	Matrix4f.`reflection(float a, float b, float c, float d)` Set this matrix to a mirror/reflection transformation that reflects about the given plane specified via the equation `xa + yb + z*c + d = 0`.
`Matrix4f`	Matrix4f.`reflection(float nx, float ny, float nz, float px, float py, float pz)` Set this matrix to a mirror/reflection transformation that reflects about the given plane specified via the plane normal and a point on the plane.
`Matrix4f`	Matrix4f.`reflection(Quaternionfc orientation, Vector3fc point)` Set this matrix to a mirror/reflection transformation that reflects about a plane specified via the plane orientation and a point on the plane.
`Matrix4f`	Matrix4f.`reflection(Vector3fc normal, Vector3fc point)` Set this matrix to a mirror/reflection transformation that reflects about the given plane specified via the plane normal and a point on the plane.
`Matrix4f`	Matrix4f.`rotate(AxisAngle4f axisAngle)` Apply a rotation transformation, rotating about the given `AxisAngle4f`, to this matrix.
`Matrix4f`	Matrix4fc.`rotate(AxisAngle4f axisAngle, Matrix4f dest)` Apply a rotation transformation, rotating about the given `AxisAngle4f` and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotate(AxisAngle4f axisAngle, Matrix4f dest)` Apply a rotation transformation, rotating about the given `AxisAngle4f` and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotate(float ang, float x, float y, float z)` Apply rotation to this matrix by rotating the given amount of radians about the specified `(x, y, z)` axis.
`Matrix4f`	Matrix4fc.`rotate(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotate(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotate(float angle, Vector3fc axis)` Apply a rotation transformation, rotating the given radians about the specified axis, to this matrix.
`Matrix4f`	Matrix4fc.`rotate(float angle, Vector3fc axis, Matrix4f dest)` Apply a rotation transformation, rotating the given radians about the specified axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotate(float angle, Vector3fc axis, Matrix4f dest)` Apply a rotation transformation, rotating the given radians about the specified axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotate(Quaternionfc quat)` Apply the rotation transformation of the given `Quaternionfc` to this matrix.
`Matrix4f`	Matrix4fc.`rotate(Quaternionfc quat, Matrix4f dest)` Apply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotate(Quaternionfc quat, Matrix4f dest)` Apply the rotation transformation of the given `Quaternionfc` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffine(float ang, float x, float y, float z)` Apply rotation to this `affine` matrix by rotating the given amount of radians about the specified `(x, y, z)` axis.
`Matrix4f`	Matrix4fc.`rotateAffine(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this `affine` matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffine(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this `affine` matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffine(Quaternionfc quat)` Apply the rotation transformation of the given `Quaternionfc` to this matrix.
`Matrix4f`	Matrix4fc.`rotateAffine(Quaternionfc quat, Matrix4f dest)` Apply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this `affine` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffine(Quaternionfc quat, Matrix4f dest)` Apply the rotation transformation of the given `Quaternionfc` to this `affine` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffineXYZ(float angleX, float angleY, float angleZ)` Apply rotation of `angleX` radians about the X axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleZ` radians about the Z axis.
`Matrix4f`	Matrix4fc.`rotateAffineXYZ(float angleX, float angleY, float angleZ, Matrix4f dest)` Apply rotation of `angleX` radians about the X axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleZ` radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffineXYZ(float angleX, float angleY, float angleZ, Matrix4f dest)`
`Matrix4f`	Matrix4f.`rotateAffineYXZ(float angleY, float angleX, float angleZ)` Apply rotation of `angleY` radians about the Y axis, followed by a rotation of `angleX` radians about the X axis and followed by a rotation of `angleZ` radians about the Z axis.
`Matrix4f`	Matrix4fc.`rotateAffineYXZ(float angleY, float angleX, float angleZ, Matrix4f dest)` Apply rotation of `angleY` radians about the Y axis, followed by a rotation of `angleX` radians about the X axis and followed by a rotation of `angleZ` radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffineYXZ(float angleY, float angleX, float angleZ, Matrix4f dest)`
`Matrix4f`	Matrix4f.`rotateAffineZYX(float angleZ, float angleY, float angleX)` Apply rotation of `angleZ` radians about the Z axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleX` radians about the X axis.
`Matrix4f`	Matrix4fc.`rotateAffineZYX(float angleZ, float angleY, float angleX, Matrix4f dest)` Apply rotation of `angleZ` radians about the Z axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleX` radians about the X axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffineZYX(float angleZ, float angleY, float angleX, Matrix4f dest)`
`Matrix4f`	Matrix4f.`rotateAround(Quaternionfc quat, float ox, float oy, float oz)` Apply the rotation transformation of the given `Quaternionfc` to this matrix while using `(ox, oy, oz)` as the rotation origin.
`Matrix4f`	Matrix4fc.`rotateAround(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)` Apply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this matrix while using `(ox, oy, oz)` as the rotation origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAround(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateAroundAffine(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)` Apply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this `affine` matrix while using `(ox, oy, oz)` as the rotation origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAroundAffine(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4f.`rotateAroundLocal(Quaternionfc quat, float ox, float oy, float oz)` Pre-multiply the rotation transformation of the given `Quaternionfc` to this matrix while using `(ox, oy, oz)` as the rotation origin.
`Matrix4f`	Matrix4fc.`rotateAroundLocal(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)` Pre-multiply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this matrix while using `(ox, oy, oz)` as the rotation origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAroundLocal(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4f.`rotateLocal(float ang, float x, float y, float z)` Pre-multiply a rotation to this matrix by rotating the given amount of radians about the specified `(x, y, z)` axis.
`Matrix4f`	Matrix4fc.`rotateLocal(float ang, float x, float y, float z, Matrix4f dest)` Pre-multiply a rotation to this matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocal(float ang, float x, float y, float z, Matrix4f dest)` Pre-multiply a rotation to this matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocal(Quaternionfc quat)` Pre-multiply the rotation transformation of the given `Quaternionfc` to this matrix.
`Matrix4f`	Matrix4fc.`rotateLocal(Quaternionfc quat, Matrix4f dest)` Pre-multiply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocal(Quaternionfc quat, Matrix4f dest)` Pre-multiply the rotation transformation of the given `Quaternionfc` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocalX(float ang)` Pre-multiply a rotation to this matrix by rotating the given amount of radians about the X axis.
`Matrix4f`	Matrix4fc.`rotateLocalX(float ang, Matrix4f dest)` Pre-multiply a rotation around the X axis to this matrix by rotating the given amount of radians about the X axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocalX(float ang, Matrix4f dest)` Pre-multiply a rotation around the X axis to this matrix by rotating the given amount of radians about the X axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocalY(float ang)` Pre-multiply a rotation to this matrix by rotating the given amount of radians about the Y axis.
`Matrix4f`	Matrix4fc.`rotateLocalY(float ang, Matrix4f dest)` Pre-multiply a rotation around the Y axis to this matrix by rotating the given amount of radians about the Y axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocalY(float ang, Matrix4f dest)` Pre-multiply a rotation around the Y axis to this matrix by rotating the given amount of radians about the Y axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocalZ(float ang)` Pre-multiply a rotation to this matrix by rotating the given amount of radians about the Z axis.
`Matrix4f`	Matrix4fc.`rotateLocalZ(float ang, Matrix4f dest)` Pre-multiply a rotation around the Z axis to this matrix by rotating the given amount of radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocalZ(float ang, Matrix4f dest)` Pre-multiply a rotation around the Z axis to this matrix by rotating the given amount of radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTowards(float dirX, float dirY, float dirZ, float upX, float upY, float upZ)` Apply a model transformation to this matrix for a right-handed coordinate system, that aligns the local `+Z` axis with `(dirX, dirY, dirZ)`.
`Matrix4f`	Matrix4fc.`rotateTowards(float dirX, float dirY, float dirZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a model transformation to this matrix for a right-handed coordinate system, that aligns the local `+Z` axis with `(dirX, dirY, dirZ)` and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTowards(float dirX, float dirY, float dirZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a model transformation to this matrix for a right-handed coordinate system, that aligns the local `+Z` axis with `(dirX, dirY, dirZ)` and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTowards(Vector3fc dir, Vector3fc up)` Apply a model transformation to this matrix for a right-handed coordinate system, that aligns the local `+Z` axis with `dir`.
`Matrix4f`	Matrix4fc.`rotateTowards(Vector3fc dir, Vector3fc up, Matrix4f dest)` Apply a model transformation to this matrix for a right-handed coordinate system, that aligns the local `+Z` axis with `dir` and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTowards(Vector3fc dir, Vector3fc up, Matrix4f dest)` Apply a model transformation to this matrix for a right-handed coordinate system, that aligns the local `+Z` axis with `dir` and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTowardsXY(float dirX, float dirY)` Apply rotation about the Z axis to align the local `+X` towards `(dirX, dirY)`.
`Matrix4f`	Matrix4fc.`rotateTowardsXY(float dirX, float dirY, Matrix4f dest)` Apply rotation about the Z axis to align the local `+X` towards `(dirX, dirY)` and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTowardsXY(float dirX, float dirY, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateTranslation(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this matrix, which is assumed to only contain a translation, by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTranslation(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this matrix, which is assumed to only contain a translation, by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateTranslation(Quaternionfc quat, Matrix4f dest)` Apply the rotation - and possibly scaling - ransformation of the given `Quaternionfc` to this matrix, which is assumed to only contain a translation, and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTranslation(Quaternionfc quat, Matrix4f dest)` Apply the rotation transformation of the given `Quaternionfc` to this matrix, which is assumed to only contain a translation, and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateX(float ang)` Apply rotation about the X axis to this matrix by rotating the given amount of radians.
`Matrix4f`	Matrix4fc.`rotateX(float ang, Matrix4f dest)` Apply rotation about the X axis to this matrix by rotating the given amount of radians and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateX(float ang, Matrix4f dest)`
`Matrix4f`	Matrix4f.`rotateXYZ(float angleX, float angleY, float angleZ)` Apply rotation of `angleX` radians about the X axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleZ` radians about the Z axis.
`Matrix4f`	Matrix4fc.`rotateXYZ(float angleX, float angleY, float angleZ, Matrix4f dest)` Apply rotation of `angleX` radians about the X axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleZ` radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateXYZ(float angleX, float angleY, float angleZ, Matrix4f dest)`
`Matrix4f`	Matrix4f.`rotateXYZ(Vector3f angles)` Apply rotation of `angles.x` radians about the X axis, followed by a rotation of `angles.y` radians about the Y axis and followed by a rotation of `angles.z` radians about the Z axis.
`Matrix4f`	Matrix4f.`rotateY(float ang)` Apply rotation about the Y axis to this matrix by rotating the given amount of radians.
`Matrix4f`	Matrix4fc.`rotateY(float ang, Matrix4f dest)` Apply rotation about the Y axis to this matrix by rotating the given amount of radians and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateY(float ang, Matrix4f dest)`
`Matrix4f`	Matrix4f.`rotateYXZ(float angleY, float angleX, float angleZ)` Apply rotation of `angleY` radians about the Y axis, followed by a rotation of `angleX` radians about the X axis and followed by a rotation of `angleZ` radians about the Z axis.
`Matrix4f`	Matrix4fc.`rotateYXZ(float angleY, float angleX, float angleZ, Matrix4f dest)` Apply rotation of `angleY` radians about the Y axis, followed by a rotation of `angleX` radians about the X axis and followed by a rotation of `angleZ` radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateYXZ(float angleY, float angleX, float angleZ, Matrix4f dest)`
`Matrix4f`	Matrix4f.`rotateYXZ(Vector3f angles)` Apply rotation of `angles.y` radians about the Y axis, followed by a rotation of `angles.x` radians about the X axis and followed by a rotation of `angles.z` radians about the Z axis.
`Matrix4f`	Matrix4f.`rotateZ(float ang)` Apply rotation about the Z axis to this matrix by rotating the given amount of radians.
`Matrix4f`	Matrix4fc.`rotateZ(float ang, Matrix4f dest)` Apply rotation about the Z axis to this matrix by rotating the given amount of radians and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateZ(float ang, Matrix4f dest)`
`Matrix4f`	Matrix4f.`rotateZYX(float angleZ, float angleY, float angleX)` Apply rotation of `angleZ` radians about the Z axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleX` radians about the X axis.
`Matrix4f`	Matrix4fc.`rotateZYX(float angleZ, float angleY, float angleX, Matrix4f dest)` Apply rotation of `angleZ` radians about the Z axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleX` radians about the X axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateZYX(float angleZ, float angleY, float angleX, Matrix4f dest)`
`Matrix4f`	Matrix4f.`rotateZYX(Vector3f angles)` Apply rotation of `angles.z` radians about the Z axis, followed by a rotation of `angles.y` radians about the Y axis and followed by a rotation of `angles.x` radians about the X axis.
`Matrix4f`	Matrix4f.`rotation(AxisAngle4f axisAngle)` Set this matrix to a rotation transformation using the given `AxisAngle4f`.
`Matrix4f`	Matrix4f.`rotation(float angle, float x, float y, float z)` Set this matrix to a rotation matrix which rotates the given radians about a given axis.
`Matrix4f`	Matrix4f.`rotation(float angle, Vector3fc axis)` Set this matrix to a rotation matrix which rotates the given radians about a given axis.
`Matrix4f`	Matrix4f.`rotation(Quaternionfc quat)` Set this matrix to the rotation transformation of the given `Quaternionfc`.
`Matrix4f`	Matrix4f.`rotationAround(Quaternionfc quat, float ox, float oy, float oz)` Set this matrix to a transformation composed of a rotation of the specified `Quaternionfc` while using `(ox, oy, oz)` as the rotation origin.
`Matrix4f`	Matrix4f.`rotationTowards(float dirX, float dirY, float dirZ, float upX, float upY, float upZ)` Set this matrix to a model transformation for a right-handed coordinate system, that aligns the local `-z` axis with `(dirX, dirY, dirZ)`.
`Matrix4f`	Matrix4f.`rotationTowards(Vector3fc dir, Vector3fc up)` Set this matrix to a model transformation for a right-handed coordinate system, that aligns the local `-z` axis with `dir`.
`Matrix4f`	Matrix4f.`rotationTowardsXY(float dirX, float dirY)` Set this matrix to a rotation transformation about the Z axis to align the local `+X` towards `(dirX, dirY)`.
`Matrix4f`	Matrix4f.`rotationX(float ang)` Set this matrix to a rotation transformation about the X axis.
`Matrix4f`	Matrix4f.`rotationXYZ(float angleX, float angleY, float angleZ)` Set this matrix to a rotation of `angleX` radians about the X axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleZ` radians about the Z axis.
`Matrix4f`	Matrix4f.`rotationY(float ang)` Set this matrix to a rotation transformation about the Y axis.
`Matrix4f`	Matrix4f.`rotationYXZ(float angleY, float angleX, float angleZ)` Set this matrix to a rotation of `angleY` radians about the Y axis, followed by a rotation of `angleX` radians about the X axis and followed by a rotation of `angleZ` radians about the Z axis.
`Matrix4f`	Matrix4f.`rotationZ(float ang)` Set this matrix to a rotation transformation about the Z axis.
`Matrix4f`	Matrix4f.`rotationZYX(float angleZ, float angleY, float angleX)` Set this matrix to a rotation of `angleZ` radians about the Z axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleX` radians about the X axis.
`Matrix4f`	Matrix4f.`scale(float xyz)` Apply scaling to this matrix by uniformly scaling all base axes by the given `xyz` factor.
`Matrix4f`	Matrix4f.`scale(float x, float y, float z)` Apply scaling to this matrix by scaling the base axes by the given sx, sy and sz factors.
`Matrix4f`	Matrix4fc.`scale(float x, float y, float z, Matrix4f dest)` Apply scaling to `this` matrix by scaling the base axes by the given x, y and z factors and store the result in `dest`.
`Matrix4f`	Matrix4f.`scale(float x, float y, float z, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scale(float xyz, Matrix4f dest)` Apply scaling to this matrix by uniformly scaling all base axes by the given `xyz` factor and store the result in `dest`.
`Matrix4f`	Matrix4f.`scale(float xyz, Matrix4f dest)`
`Matrix4f`	Matrix4f.`scale(Vector3fc xyz)` Apply scaling to this matrix by scaling the base axes by the given `xyz.x`, `xyz.y` and `xyz.z` factors, respectively.
`Matrix4f`	Matrix4fc.`scale(Vector3fc xyz, Matrix4f dest)` Apply scaling to `this` matrix by scaling the base axes by the given `xyz.x`, `xyz.y` and `xyz.z` factors, respectively and store the result in `dest`.
`Matrix4f`	Matrix4f.`scale(Vector3fc xyz, Matrix4f dest)`
`Matrix4f`	Matrix4f.`scaleAround(float factor, float ox, float oy, float oz)` Apply scaling to this matrix by scaling all three base axes by the given `factor` while using `(ox, oy, oz)` as the scaling origin.
`Matrix4f`	Matrix4f.`scaleAround(float sx, float sy, float sz, float ox, float oy, float oz)` Apply scaling to this matrix by scaling the base axes by the given sx, sy and sz factors while using `(ox, oy, oz)` as the scaling origin.
`Matrix4f`	Matrix4fc.`scaleAround(float sx, float sy, float sz, float ox, float oy, float oz, Matrix4f dest)` Apply scaling to `this` matrix by scaling the base axes by the given sx, sy and sz factors while using `(ox, oy, oz)` as the scaling origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleAround(float sx, float sy, float sz, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scaleAround(float factor, float ox, float oy, float oz, Matrix4f dest)` Apply scaling to this matrix by scaling all three base axes by the given `factor` while using `(ox, oy, oz)` as the scaling origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleAround(float factor, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4f.`scaleAroundLocal(float factor, float ox, float oy, float oz)` Pre-multiply scaling to this matrix by scaling all three base axes by the given `factor` while using `(ox, oy, oz)` as the scaling origin.
`Matrix4f`	Matrix4f.`scaleAroundLocal(float sx, float sy, float sz, float ox, float oy, float oz)` Pre-multiply scaling to this matrix by scaling the base axes by the given sx, sy and sz factors while using `(ox, oy, oz)` as the scaling origin.
`Matrix4f`	Matrix4fc.`scaleAroundLocal(float sx, float sy, float sz, float ox, float oy, float oz, Matrix4f dest)` Pre-multiply scaling to `this` matrix by scaling the base axes by the given sx, sy and sz factors while using the given `(ox, oy, oz)` as the scaling origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleAroundLocal(float sx, float sy, float sz, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scaleAroundLocal(float factor, float ox, float oy, float oz, Matrix4f dest)` Pre-multiply scaling to this matrix by scaling all three base axes by the given `factor` while using `(ox, oy, oz)` as the scaling origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleAroundLocal(float factor, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4f.`scaleLocal(float xyz)` Pre-multiply scaling to this matrix by scaling the base axes by the given xyz factor.
`Matrix4f`	Matrix4f.`scaleLocal(float x, float y, float z)` Pre-multiply scaling to this matrix by scaling the base axes by the given x, y and z factors.
`Matrix4f`	Matrix4fc.`scaleLocal(float x, float y, float z, Matrix4f dest)` Pre-multiply scaling to `this` matrix by scaling the base axes by the given x, y and z factors and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleLocal(float x, float y, float z, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scaleLocal(float xyz, Matrix4f dest)` Pre-multiply scaling to `this` matrix by scaling all base axes by the given `xyz` factor, and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleLocal(float xyz, Matrix4f dest)`
`Matrix4f`	Matrix4f.`scaleXY(float x, float y)` Apply scaling to this matrix by scaling the X axis by `x` and the Y axis by `y`.
`Matrix4f`	Matrix4fc.`scaleXY(float x, float y, Matrix4f dest)` Apply scaling to this matrix by by scaling the X axis by `x` and the Y axis by `y` and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleXY(float x, float y, Matrix4f dest)`
`Matrix4f`	Matrix4f.`scaling(float factor)` Set this matrix to be a simple scale matrix, which scales all axes uniformly by the given factor.
`Matrix4f`	Matrix4f.`scaling(float x, float y, float z)` Set this matrix to be a simple scale matrix.
`Matrix4f`	Matrix4f.`scaling(Vector3fc xyz)` Set this matrix to be a simple scale matrix which scales the base axes by `xyz.x`, `xyz.y` and `xyz.z` respectively.
`Matrix4f`	Matrix4f.`set(AxisAngle4d axisAngle)` Set this matrix to be equivalent to the rotation specified by the given `AxisAngle4d`.
`Matrix4f`	Matrix4f.`set(AxisAngle4f axisAngle)` Set this matrix to be equivalent to the rotation specified by the given `AxisAngle4f`.
`Matrix4f`	Matrix4f.`set(ByteBuffer buffer)` Set the values of this matrix by reading 16 float values from the given `ByteBuffer` in column-major order, starting at its current position.
`Matrix4f`	Matrix4f.`set(float[] m)` Set the values in the matrix using a float array that contains the matrix elements in column-major order.
`Matrix4f`	Matrix4f.`set(float[] m, int off)` Set the values in the matrix using a float array that contains the matrix elements in column-major order.
`Matrix4f`	Matrix4f.`set(FloatBuffer buffer)` Set the values of this matrix by reading 16 float values from the given `FloatBuffer` in column-major order, starting at its current position.
`Matrix4f`	Matrix4f.`set(float m00, float m01, float m02, float m03, float m10, float m11, float m12, float m13, float m20, float m21, float m22, float m23, float m30, float m31, float m32, float m33)` Set the values within this matrix to the supplied float values.
`Matrix4f`	Matrix4f.`set(Matrix3fc mat)` Set the upper left 3x3 submatrix of this `Matrix4f` to the given `Matrix3fc` and the rest to identity.
`Matrix4f`	Matrix4f.`set(Matrix4dc m)` Store the values of the given matrix `m` into `this` matrix.
`Matrix4f`	Matrix4f.`set(Matrix4fc m)` Store the values of the given matrix `m` into `this` matrix.
`Matrix4f`	Matrix4f.`set(Matrix4x3fc m)` Store the values of the given matrix `m` into `this` matrix and set the other matrix elements to identity.
`Matrix4f`	Matrix4f.`set(Quaterniondc q)` Set this matrix to be equivalent to the rotation specified by the given `Quaterniondc`.
`Matrix4f`	Matrix4f.`set(Quaternionfc q)` Set this matrix to be equivalent to the rotation specified by the given `Quaternionfc`.
`Matrix4f`	Matrix4f.`set(Vector4fc col0, Vector4fc col1, Vector4fc col2, Vector4fc col3)` Set the four columns of this matrix to the supplied vectors, respectively.
`Matrix4f`	Matrix4f.`set3x3(Matrix3fc mat)` Set the upper left 3x3 submatrix of this `Matrix4f` to the given `Matrix3fc` and don't change the other elements.
`Matrix4f`	Matrix4f.`set3x3(Matrix4f mat)` Set the upper left 3x3 submatrix of this `Matrix4f` to that of the given `Matrix4f` and don't change the other elements.
`Matrix4f`	Matrix4f.`set4x3(Matrix4f mat)` Set the upper 4x3 submatrix of this `Matrix4f` to the upper 4x3 submatrix of the given `Matrix4f` and don't change the other elements.
`Matrix4f`	Matrix4f.`set4x3(Matrix4x3fc mat)` Set the upper 4x3 submatrix of this `Matrix4f` to the given `Matrix4x3fc` and don't change the other elements.
`Matrix4f`	Matrix4f.`setColumn(int column, Vector4fc src)` Set the column at the given `column` index, starting with `0`.
`Matrix4f`	Matrix4f.`setFromIntrinsic(float alphaX, float alphaY, float gamma, float u0, float v0, int imgWidth, int imgHeight, float near, float far)` Set this matrix to represent a perspective projection equivalent to the given intrinsic camera calibration parameters.
`Matrix4f`	Matrix4f.`setFrustum(float left, float right, float bottom, float top, float zNear, float zFar)` Set this matrix to be an arbitrary perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setFrustum(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne)` Set this matrix to be an arbitrary perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range.
`Matrix4f`	Matrix4f.`setFrustumLH(float left, float right, float bottom, float top, float zNear, float zFar)` Set this matrix to be an arbitrary perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setFrustumLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne)` Set this matrix to be an arbitrary perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setLookAlong(float dirX, float dirY, float dirZ, float upX, float upY, float upZ)` Set this matrix to a rotation transformation to make `-z` point along `dir`.
`Matrix4f`	Matrix4f.`setLookAlong(Vector3fc dir, Vector3fc up)` Set this matrix to a rotation transformation to make `-z` point along `dir`.
`Matrix4f`	Matrix4f.`setLookAt(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ)` Set this matrix to be a "lookat" transformation for a right-handed coordinate system, that aligns `-z` with `center - eye`.
`Matrix4f`	Matrix4f.`setLookAt(Vector3fc eye, Vector3fc center, Vector3fc up)` Set this matrix to be a "lookat" transformation for a right-handed coordinate system, that aligns `-z` with `center - eye`.
`Matrix4f`	Matrix4f.`setLookAtLH(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ)` Set this matrix to be a "lookat" transformation for a left-handed coordinate system, that aligns `+z` with `center - eye`.
`Matrix4f`	Matrix4f.`setLookAtLH(Vector3fc eye, Vector3fc center, Vector3fc up)` Set this matrix to be a "lookat" transformation for a left-handed coordinate system, that aligns `+z` with `center - eye`.
`Matrix4f`	Matrix4f.`setOrtho(float left, float right, float bottom, float top, float zNear, float zFar)` Set this matrix to be an orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setOrtho(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne)` Set this matrix to be an orthographic projection transformation for a right-handed coordinate system using the given NDC z range.
`Matrix4f`	Matrix4f.`setOrtho2D(float left, float right, float bottom, float top)` Set this matrix to be an orthographic projection transformation for a right-handed coordinate system.
`Matrix4f`	Matrix4f.`setOrtho2DLH(float left, float right, float bottom, float top)` Set this matrix to be an orthographic projection transformation for a left-handed coordinate system.
`Matrix4f`	Matrix4f.`setOrthoLH(float left, float right, float bottom, float top, float zNear, float zFar)` Set this matrix to be an orthographic projection transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setOrthoLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne)` Set this matrix to be an orthographic projection transformation for a left-handed coordinate system using the given NDC z range.
`Matrix4f`	Matrix4f.`setOrthoSymmetric(float width, float height, float zNear, float zFar)` Set this matrix to be a symmetric orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setOrthoSymmetric(float width, float height, float zNear, float zFar, boolean zZeroToOne)` Set this matrix to be a symmetric orthographic projection transformation for a right-handed coordinate system using the given NDC z range.
`Matrix4f`	Matrix4f.`setOrthoSymmetricLH(float width, float height, float zNear, float zFar)` Set this matrix to be a symmetric orthographic projection transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setOrthoSymmetricLH(float width, float height, float zNear, float zFar, boolean zZeroToOne)` Set this matrix to be a symmetric orthographic projection transformation for a left-handed coordinate system using the given NDC z range.
`Matrix4f`	Matrix4f.`setPerspective(float fovy, float aspect, float zNear, float zFar)` Set this matrix to be a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setPerspective(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne)` Set this matrix to be a symmetric perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range.
`Matrix4f`	Matrix4f.`setPerspectiveLH(float fovy, float aspect, float zNear, float zFar)` Set this matrix to be a symmetric perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setPerspectiveLH(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne)` Set this matrix to be a symmetric perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setPerspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar)` Set this matrix to be an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setPerspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar, boolean zZeroToOne)` Set this matrix to be an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range.
`Matrix4f`	Matrix4f.`setPerspectiveRect(float width, float height, float zNear, float zFar)` Set this matrix to be a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]`.
`Matrix4f`	Matrix4f.`setPerspectiveRect(float width, float height, float zNear, float zFar, boolean zZeroToOne)` Set this matrix to be a symmetric perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range.
`Matrix4f`	Matrix4f.`setRotationXYZ(float angleX, float angleY, float angleZ)` Set only the upper left 3x3 submatrix of this matrix to a rotation of `angleX` radians about the X axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleZ` radians about the Z axis.
`Matrix4f`	Matrix4f.`setRotationYXZ(float angleY, float angleX, float angleZ)` Set only the upper left 3x3 submatrix of this matrix to a rotation of `angleY` radians about the Y axis, followed by a rotation of `angleX` radians about the X axis and followed by a rotation of `angleZ` radians about the Z axis.
`Matrix4f`	Matrix4f.`setRotationZYX(float angleZ, float angleY, float angleX)` Set only the upper left 3x3 submatrix of this matrix to a rotation of `angleZ` radians about the Z axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleX` radians about the X axis.
`Matrix4f`	Matrix4f.`setRow(int row, Vector4fc src)` Set the row at the given `row` index, starting with `0`.
`Matrix4f`	Matrix4f.`setTranslation(float x, float y, float z)` Set only the translation components `(m30, m31, m32)` of this matrix to the given values `(x, y, z)`.
`Matrix4f`	Matrix4f.`setTranslation(Vector3fc xyz)` Set only the translation components `(m30, m31, m32)` of this matrix to the values `(xyz.x, xyz.y, xyz.z)`.
`Matrix4f`	Matrix4f.`shadow(float lightX, float lightY, float lightZ, float lightW, float a, float b, float c, float d)` Apply a projection transformation to this matrix that projects onto the plane specified via the general plane equation `xa + yb + z*c + d = 0` as if casting a shadow from a given light position/direction `(lightX, lightY, lightZ, lightW)`.
`Matrix4f`	Matrix4fc.`shadow(float lightX, float lightY, float lightZ, float lightW, float a, float b, float c, float d, Matrix4f dest)` Apply a projection transformation to this matrix that projects onto the plane specified via the general plane equation `xa + yb + z*c + d = 0` as if casting a shadow from a given light position/direction `(lightX, lightY, lightZ, lightW)` and store the result in `dest`.
`Matrix4f`	Matrix4f.`shadow(float lightX, float lightY, float lightZ, float lightW, float a, float b, float c, float d, Matrix4f dest)`
`Matrix4f`	Matrix4f.`shadow(float lightX, float lightY, float lightZ, float lightW, Matrix4f planeTransform)` Apply a projection transformation to this matrix that projects onto the plane with the general plane equation `y = 0` as if casting a shadow from a given light position/direction `(lightX, lightY, lightZ, lightW)`.
`Matrix4f`	Matrix4fc.`shadow(float lightX, float lightY, float lightZ, float lightW, Matrix4fc planeTransform, Matrix4f dest)` Apply a projection transformation to this matrix that projects onto the plane with the general plane equation `y = 0` as if casting a shadow from a given light position/direction `(lightX, lightY, lightZ, lightW)` and store the result in `dest`.
`Matrix4f`	Matrix4f.`shadow(float lightX, float lightY, float lightZ, float lightW, Matrix4fc planeTransform, Matrix4f dest)`
`Matrix4f`	Matrix4f.`shadow(Vector4f light, float a, float b, float c, float d)` Apply a projection transformation to this matrix that projects onto the plane specified via the general plane equation `xa + yb + z*c + d = 0` as if casting a shadow from a given light position/direction `light`.
`Matrix4f`	Matrix4fc.`shadow(Vector4f light, float a, float b, float c, float d, Matrix4f dest)` Apply a projection transformation to this matrix that projects onto the plane specified via the general plane equation `xa + yb + z*c + d = 0` as if casting a shadow from a given light position/direction `light` and store the result in `dest`.
`Matrix4f`	Matrix4f.`shadow(Vector4f light, float a, float b, float c, float d, Matrix4f dest)`
`Matrix4f`	Matrix4f.`shadow(Vector4f light, Matrix4f planeTransform)` Apply a projection transformation to this matrix that projects onto the plane with the general plane equation `y = 0` as if casting a shadow from a given light position/direction `light`.
`Matrix4f`	Matrix4fc.`shadow(Vector4f light, Matrix4fc planeTransform, Matrix4f dest)` Apply a projection transformation to this matrix that projects onto the plane with the general plane equation `y = 0` as if casting a shadow from a given light position/direction `light` and store the result in `dest`.
`Matrix4f`	Matrix4f.`shadow(Vector4f light, Matrix4fc planeTransform, Matrix4f dest)`
`Matrix4f`	Matrix4f.`sub(Matrix4fc subtrahend)` Component-wise subtract `subtrahend` from `this`.
`Matrix4f`	Matrix4fc.`sub(Matrix4fc subtrahend, Matrix4f dest)` Component-wise subtract `subtrahend` from `this` and store the result in `dest`.
`Matrix4f`	Matrix4f.`sub(Matrix4fc subtrahend, Matrix4f dest)`
`Matrix4f`	Matrix4f.`sub4x3(Matrix4f subtrahend)` Component-wise subtract the upper 4x3 submatrices of `subtrahend` from `this`.
`Matrix4f`	Matrix4fc.`sub4x3(Matrix4fc subtrahend, Matrix4f dest)` Component-wise subtract the upper 4x3 submatrices of `subtrahend` from `this` and store the result in `dest`.
`Matrix4f`	Matrix4f.`sub4x3(Matrix4fc subtrahend, Matrix4f dest)`
`Matrix4f`	Matrix4f.`swap(Matrix4f other)` Exchange the values of `this` matrix with the given `other` matrix.
`Matrix4f`	Matrix4fc.`transformAab(float minX, float minY, float minZ, float maxX, float maxY, float maxZ, Vector3f outMin, Vector3f outMax)` Transform the axis-aligned box given as the minimum corner `(minX, minY, minZ)` and maximum corner `(maxX, maxY, maxZ)` by `this` `affine` matrix and compute the axis-aligned box of the result whose minimum corner is stored in `outMin` and maximum corner stored in `outMax`.
`Matrix4f`	Matrix4f.`transformAab(float minX, float minY, float minZ, float maxX, float maxY, float maxZ, Vector3f outMin, Vector3f outMax)`
`Matrix4f`	Matrix4fc.`transformAab(Vector3fc min, Vector3fc max, Vector3f outMin, Vector3f outMax)` Transform the axis-aligned box given as the minimum corner `min` and maximum corner `max` by `this` `affine` matrix and compute the axis-aligned box of the result whose minimum corner is stored in `outMin` and maximum corner stored in `outMax`.
`Matrix4f`	Matrix4f.`transformAab(Vector3fc min, Vector3fc max, Vector3f outMin, Vector3f outMax)`
`Matrix4f`	Matrix4f.`translate(float x, float y, float z)` Apply a translation to this matrix by translating by the given number of units in x, y and z.
`Matrix4f`	Matrix4fc.`translate(float x, float y, float z, Matrix4f dest)` Apply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translate(float x, float y, float z, Matrix4f dest)` Apply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translate(Vector3fc offset)` Apply a translation to this matrix by translating by the given number of units in x, y and z.
`Matrix4f`	Matrix4fc.`translate(Vector3fc offset, Matrix4f dest)` Apply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translate(Vector3fc offset, Matrix4f dest)` Apply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translateLocal(float x, float y, float z)` Pre-multiply a translation to this matrix by translating by the given number of units in x, y and z.
`Matrix4f`	Matrix4fc.`translateLocal(float x, float y, float z, Matrix4f dest)` Pre-multiply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translateLocal(float x, float y, float z, Matrix4f dest)` Pre-multiply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translateLocal(Vector3fc offset)` Pre-multiply a translation to this matrix by translating by the given number of units in x, y and z.
`Matrix4f`	Matrix4fc.`translateLocal(Vector3fc offset, Matrix4f dest)` Pre-multiply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translateLocal(Vector3fc offset, Matrix4f dest)` Pre-multiply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translation(float x, float y, float z)` Set this matrix to be a simple translation matrix.
`Matrix4f`	Matrix4f.`translation(Vector3fc offset)` Set this matrix to be a simple translation matrix.
`Matrix4f`	Matrix4f.`translationRotate(float tx, float ty, float tz, float qx, float qy, float qz, float qw)` Set `this` matrix to `T * R`, where `T` is a translation by the given `(tx, ty, tz)` and `R` is a rotation - and possibly scaling - transformation specified by the quaternion `(qx, qy, qz, qw)`.
`Matrix4f`	Matrix4f.`translationRotate(float tx, float ty, float tz, Quaternionfc quat)` Set `this` matrix to `T * R`, where `T` is a translation by the given `(tx, ty, tz)` and `R` is a rotation - and possibly scaling - transformation specified by the given quaternion.
`Matrix4f`	Matrix4f.`translationRotateScale(float tx, float ty, float tz, float qx, float qy, float qz, float qw, float scale)` Set `this` matrix to `T * R * S`, where `T` is a translation by the given `(tx, ty, tz)`, `R` is a rotation transformation specified by the quaternion `(qx, qy, qz, qw)`, and `S` is a scaling transformation which scales all three axes by `scale`.
`Matrix4f`	Matrix4f.`translationRotateScale(float tx, float ty, float tz, float qx, float qy, float qz, float qw, float sx, float sy, float sz)` Set `this` matrix to `T * R * S`, where `T` is a translation by the given `(tx, ty, tz)`, `R` is a rotation transformation specified by the quaternion `(qx, qy, qz, qw)`, and `S` is a scaling transformation which scales the three axes x, y and z by `(sx, sy, sz)`.
`Matrix4f`	Matrix4f.`translationRotateScale(Vector3fc translation, Quaternionfc quat, float scale)` Set `this` matrix to `T * R * S`, where `T` is the given `translation`, `R` is a rotation transformation specified by the given quaternion, and `S` is a scaling transformation which scales all three axes by `scale`.
`Matrix4f`	Matrix4f.`translationRotateScale(Vector3fc translation, Quaternionfc quat, Vector3fc scale)` Set `this` matrix to `T * R * S`, where `T` is the given `translation`, `R` is a rotation transformation specified by the given quaternion, and `S` is a scaling transformation which scales the axes by `scale`.
`Matrix4f`	Matrix4f.`translationRotateScaleInvert(float tx, float ty, float tz, float qx, float qy, float qz, float qw, float sx, float sy, float sz)` Set `this` matrix to `(T * R * S)^-1`, where `T` is a translation by the given `(tx, ty, tz)`, `R` is a rotation transformation specified by the quaternion `(qx, qy, qz, qw)`, and `S` is a scaling transformation which scales the three axes x, y and z by `(sx, sy, sz)`.
`Matrix4f`	Matrix4f.`translationRotateScaleInvert(Vector3fc translation, Quaternionfc quat, float scale)` Set `this` matrix to `(T * R * S)^-1`, where `T` is the given `translation`, `R` is a rotation transformation specified by the given quaternion, and `S` is a scaling transformation which scales all three axes by `scale`.
`Matrix4f`	Matrix4f.`translationRotateScaleInvert(Vector3fc translation, Quaternionfc quat, Vector3fc scale)` Set `this` matrix to `(T * R * S)^-1`, where `T` is the given `translation`, `R` is a rotation transformation specified by the given quaternion, and `S` is a scaling transformation which scales the axes by `scale`.
`Matrix4f`	Matrix4f.`translationRotateScaleMulAffine(float tx, float ty, float tz, float qx, float qy, float qz, float qw, float sx, float sy, float sz, Matrix4f m)` Set `this` matrix to `T * R * S * M`, where `T` is a translation by the given `(tx, ty, tz)`, `R` is a rotation - and possibly scaling - transformation specified by the quaternion `(qx, qy, qz, qw)`, `S` is a scaling transformation which scales the three axes x, y and z by `(sx, sy, sz)` and `M` is an `affine` matrix.
`Matrix4f`	Matrix4f.`translationRotateScaleMulAffine(Vector3fc translation, Quaternionfc quat, Vector3fc scale, Matrix4f m)` Set `this` matrix to `T * R * S * M`, where `T` is the given `translation`, `R` is a rotation - and possibly scaling - transformation specified by the given quaternion, `S` is a scaling transformation which scales the axes by `scale` and `M` is an `affine` matrix.
`Matrix4f`	Matrix4f.`translationRotateTowards(float posX, float posY, float posZ, float dirX, float dirY, float dirZ, float upX, float upY, float upZ)` Set this matrix to a model transformation for a right-handed coordinate system, that translates to the given `(posX, posY, posZ)` and aligns the local `-z` axis with `(dirX, dirY, dirZ)`.
`Matrix4f`	Matrix4f.`translationRotateTowards(Vector3fc pos, Vector3fc dir, Vector3fc up)` Set this matrix to a model transformation for a right-handed coordinate system, that translates to the given `pos` and aligns the local `-z` axis with `dir`.
`Matrix4f`	Matrix4f.`transpose()` Transpose this matrix.
`Matrix4f`	Matrix4fc.`transpose(Matrix4f dest)` Transpose this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`transpose(Matrix4f dest)`
`Matrix4f`	Matrix4f.`transpose3x3()` Transpose only the upper left 3x3 submatrix of this matrix.
`Matrix4f`	Matrix4fc.`transpose3x3(Matrix4f dest)` Transpose only the upper left 3x3 submatrix of this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`transpose3x3(Matrix4f dest)`
`Matrix4f`	Matrix4f.`trapezoidCrop(float p0x, float p0y, float p1x, float p1y, float p2x, float p2y, float p3x, float p3y)` Set `this` matrix to a perspective transformation that maps the trapezoid spanned by the four corner coordinates `(p0x, p0y)`, `(p1x, p1y)`, `(p2x, p2y)` and `(p3x, p3y)` to the unit square `[(-1, -1)..(+1, +1)]`.
`Matrix4f`	Matrix4fc.`unprojectInvRay(float winX, float winY, int[] viewport, Vector3f originDest, Vector3f dirDest)` Unproject the given 2D window coordinates `(winX, winY)` by `this` matrix using the specified viewport and compute the origin and the direction of the resulting ray which starts at NDC `z = -1.0` and goes through NDC `z = +1.0`.
`Matrix4f`	Matrix4f.`unprojectInvRay(float winX, float winY, int[] viewport, Vector3f originDest, Vector3f dirDest)`
`Matrix4f`	Matrix4fc.`unprojectInvRay(Vector2fc winCoords, int[] viewport, Vector3f originDest, Vector3f dirDest)` Unproject the given window coordinates `winCoords` by `this` matrix using the specified viewport and compute the origin and the direction of the resulting ray which starts at NDC `z = -1.0` and goes through NDC `z = +1.0`.
`Matrix4f`	Matrix4f.`unprojectInvRay(Vector2fc winCoords, int[] viewport, Vector3f originDest, Vector3f dirDest)`
`Matrix4f`	Matrix4fc.`unprojectRay(float winX, float winY, int[] viewport, Vector3f originDest, Vector3f dirDest)` Unproject the given 2D window coordinates `(winX, winY)` by `this` matrix using the specified viewport and compute the origin and the direction of the resulting ray which starts at NDC `z = -1.0` and goes through NDC `z = +1.0`.
`Matrix4f`	Matrix4f.`unprojectRay(float winX, float winY, int[] viewport, Vector3f originDest, Vector3f dirDest)`
`Matrix4f`	Matrix4fc.`unprojectRay(Vector2fc winCoords, int[] viewport, Vector3f originDest, Vector3f dirDest)` Unproject the given 2D window coordinates `winCoords` by `this` matrix using the specified viewport and compute the origin and the direction of the resulting ray which starts at NDC `z = -1.0` and goes through NDC `z = +1.0`.
`Matrix4f`	Matrix4f.`unprojectRay(Vector2fc winCoords, int[] viewport, Vector3f originDest, Vector3f dirDest)`
`Matrix4f`	Matrix4f.`withLookAtUp(float upX, float upY, float upZ)` Apply a transformation to this matrix to ensure that the local Y axis (as obtained by `positiveY(Vector3f)`) will be coplanar to the plane spanned by the local Z axis (as obtained by `positiveZ(Vector3f)`) and the given vector `(upX, upY, upZ)`.
`Matrix4f`	Matrix4fc.`withLookAtUp(float upX, float upY, float upZ, Matrix4f dest)` Apply a transformation to this matrix to ensure that the local Y axis (as obtained by `Matrix4fc.positiveY(Vector3f)`) will be coplanar to the plane spanned by the local Z axis (as obtained by `Matrix4fc.positiveZ(Vector3f)`) and the given vector `(upX, upY, upZ)`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`withLookAtUp(float upX, float upY, float upZ, Matrix4f dest)`
`Matrix4f`	Matrix4f.`withLookAtUp(Vector3fc up)` Apply a transformation to this matrix to ensure that the local Y axis (as obtained by `positiveY(Vector3f)`) will be coplanar to the plane spanned by the local Z axis (as obtained by `positiveZ(Vector3f)`) and the given vector `up`.
`Matrix4f`	Matrix4fc.`withLookAtUp(Vector3fc up, Matrix4f dest)` Apply a transformation to this matrix to ensure that the local Y axis (as obtained by `Matrix4fc.positiveY(Vector3f)`) will be coplanar to the plane spanned by the local Z axis (as obtained by `Matrix4fc.positiveZ(Vector3f)`) and the given vector `up`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`withLookAtUp(Vector3fc up, Matrix4f dest)`
`Matrix4f`	Matrix4f.`zero()` Set all the values within this matrix to `0`.

Methods in org.joml with parameters of type Matrix4f
Modifier and Type	Method and Description
`Matrix4f`	Matrix4fc.`add(Matrix4fc other, Matrix4f dest)` Component-wise add `this` and `other` and store the result in `dest`.
`Matrix4f`	Matrix4f.`add(Matrix4fc other, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`add4x3(Matrix4fc other, Matrix4f dest)` Component-wise add the upper 4x3 submatrices of `this` and `other` and store the result in `dest`.
`Matrix4f`	Matrix4f.`add4x3(Matrix4fc other, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`arcball(float radius, float centerX, float centerY, float centerZ, float angleX, float angleY, Matrix4f dest)` Apply an arcball view transformation to this matrix with the given `radius` and center `(centerX, centerY, centerZ)` position of the arcball and the specified X and Y rotation angles, and store the result in `dest`.
`Matrix4f`	Matrix4f.`arcball(float radius, float centerX, float centerY, float centerZ, float angleX, float angleY, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`arcball(float radius, Vector3fc center, float angleX, float angleY, Matrix4f dest)` Apply an arcball view transformation to this matrix with the given `radius` and `center` position of the arcball and the specified X and Y rotation angles, and store the result in `dest`.
`Matrix4f`	Matrix4f.`arcball(float radius, Vector3fc center, float angleX, float angleY, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`fma4x3(Matrix4fc other, float otherFactor, Matrix4f dest)` Component-wise add the upper 4x3 submatrices of `this` and `other` by first multiplying each component of `other`'s 4x3 submatrix by `otherFactor`, adding that to `this` and storing the final result in `dest`.
`Matrix4f`	Matrix4f.`fma4x3(Matrix4fc other, float otherFactor, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`frustum(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`frustum(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`frustum(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`frustum(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`frustumLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`frustumLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`frustumLH(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`frustumLH(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an arbitrary perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`get(Matrix4f dest)` Get the current values of `this` matrix and store them into `dest`.
`Matrix4f`	Quaternionfc.`get(Matrix4f dest)` Set the given destination matrix to the rotation represented by `this`.
`Matrix4f`	AxisAngle4f.`get(Matrix4f m)` Set the given `Matrix4f` to a rotation transformation equivalent to this `AxisAngle4f`.
`Matrix4f`	Matrix4f.`get(Matrix4f dest)` Get the current values of `this` matrix and store them into `dest`.
`Matrix4f`	AxisAngle4d.`get(Matrix4f m)` Set the given `Matrix4f` to a rotation transformation equivalent to this `AxisAngle4d`.
`Matrix4f`	Matrix3f.`get(Matrix4f dest)`
`Matrix4f`	Quaterniond.`get(Matrix4f dest)`
`Matrix4f`	Matrix3fc.`get(Matrix4f dest)` Get the current values of `this` matrix and store them as the rotational component of `dest`.
`Matrix4f`	Quaterniondc.`get(Matrix4f dest)` Set the given destination matrix to the rotation represented by `this`.
`Matrix4f`	Matrix4x3fc.`get(Matrix4f dest)` Get the current values of `this` matrix and store them into the upper 4x3 submatrix of `dest`.
`Matrix4f`	Matrix4x3f.`get(Matrix4f dest)`
`Matrix4f`	Quaternionf.`get(Matrix4f dest)`
`Matrix4f`	Matrix4fc.`invert(Matrix4f dest)` Invert this matrix and write the result into `dest`.
`Matrix4f`	Matrix4f.`invert(Matrix4f dest)`
`Matrix4f`	Matrix4fc.`invertAffine(Matrix4f dest)` Invert this matrix by assuming that it is an `affine` transformation (i.e.
`Matrix4f`	Matrix4f.`invertAffine(Matrix4f dest)`
`Matrix4f`	Matrix4fc.`invertFrustum(Matrix4f dest)` If `this` is an arbitrary perspective projection matrix obtained via one of the `frustum()` methods, then this method builds the inverse of `this` and stores it into the given `dest`.
`Matrix4f`	Matrix4f.`invertFrustum(Matrix4f dest)` If `this` is an arbitrary perspective projection matrix obtained via one of the `frustum()` methods or via `setFrustum()`, then this method builds the inverse of `this` and stores it into the given `dest`.
`Matrix4f`	Matrix4fc.`invertOrtho(Matrix4f dest)` Invert `this` orthographic projection matrix and store the result into the given `dest`.
`Matrix4f`	Matrix4f.`invertOrtho(Matrix4f dest)`
`Matrix4f`	Matrix4fc.`invertPerspective(Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods, that is, if `this` is a symmetrical perspective frustum transformation, then this method builds the inverse of `this` and stores it into the given `dest`.
`Matrix4f`	Matrix4f.`invertPerspective(Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods or via `setPerspective()`, that is, if `this` is a symmetrical perspective frustum transformation, then this method builds the inverse of `this` and stores it into the given `dest`.
`Matrix4f`	Matrix4fc.`invertPerspectiveView(Matrix4fc view, Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods, that is, if `this` is a symmetrical perspective frustum transformation and the given `view` matrix is `affine` and has unit scaling (for example by being obtained via `lookAt()`), then this method builds the inverse of `this * view` and stores it into the given `dest`.
`Matrix4f`	Matrix4f.`invertPerspectiveView(Matrix4fc view, Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods or via `setPerspective()`, that is, if `this` is a symmetrical perspective frustum transformation and the given `view` matrix is `affine` and has unit scaling (for example by being obtained via `lookAt()`), then this method builds the inverse of `this * view` and stores it into the given `dest`.
`Matrix4f`	Matrix4fc.`invertPerspectiveView(Matrix4x3fc view, Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods, that is, if `this` is a symmetrical perspective frustum transformation and the given `view` matrix has unit scaling, then this method builds the inverse of `this * view` and stores it into the given `dest`.
`Matrix4f`	Matrix4f.`invertPerspectiveView(Matrix4x3fc view, Matrix4f dest)` If `this` is a perspective projection matrix obtained via one of the `perspective()` methods or via `setPerspective()`, that is, if `this` is a symmetrical perspective frustum transformation and the given `view` matrix has unit scaling, then this method builds the inverse of `this * view` and stores it into the given `dest`.
`Matrix4f`	Matrix4fc.`lerp(Matrix4fc other, float t, Matrix4f dest)` Linearly interpolate `this` and `other` using the given interpolation factor `t` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lerp(Matrix4fc other, float t, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`lookAlong(float dirX, float dirY, float dirZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a rotation transformation to this matrix to make `-z` point along `dir` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAlong(float dirX, float dirY, float dirZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a rotation transformation to this matrix to make `-z` point along `dir` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`lookAlong(Vector3fc dir, Vector3fc up, Matrix4f dest)` Apply a rotation transformation to this matrix to make `-z` point along `dir` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAlong(Vector3fc dir, Vector3fc up, Matrix4f dest)` Apply a rotation transformation to this matrix to make `-z` point along `dir` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`lookAt(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAt(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`lookAt(Vector3fc eye, Vector3fc center, Vector3fc up, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAt(Vector3fc eye, Vector3fc center, Vector3fc up, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`lookAtLH(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAtLH(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`lookAtLH(Vector3fc eye, Vector3fc center, Vector3fc up, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAtLH(Vector3fc eye, Vector3fc center, Vector3fc up, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`lookAtPerspective(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAtPerspective(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a right-handed coordinate system, that aligns `-z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`lookAtPerspectiveLH(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4f.`lookAtPerspectiveLH(float eyeX, float eyeY, float eyeZ, float centerX, float centerY, float centerZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a "lookat" transformation to this matrix for a left-handed coordinate system, that aligns `+z` with `center - eye` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`mul(Matrix3x2fc right, Matrix4f dest)` Multiply this matrix by the supplied `right` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mul(Matrix3x2fc right, Matrix4f dest)`
`Matrix4d`	Matrix4d.`mul(Matrix4f right)` Multiply this matrix by the supplied parameter matrix.
`Matrix4f`	Matrix4fc.`mul(Matrix4fc right, Matrix4f dest)` Multiply this matrix by the supplied `right` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mul(Matrix4fc right, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mul(Matrix4x3fc right, Matrix4f dest)` Multiply this matrix by the supplied `right` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mul(Matrix4x3fc right, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mul4x3ComponentWise(Matrix4fc other, Matrix4f dest)` Component-wise multiply the upper 4x3 submatrices of `this` by `other` and store the result in `dest`.
`Matrix4f`	Matrix4f.`mul4x3ComponentWise(Matrix4fc other, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mulAffine(Matrix4fc right, Matrix4f dest)` Multiply this matrix by the supplied `right` matrix, both of which are assumed to be `affine`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulAffine(Matrix4fc right, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mulAffineR(Matrix4fc right, Matrix4f dest)` Multiply this matrix by the supplied `right` matrix, which is assumed to be `affine`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulAffineR(Matrix4fc right, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mulComponentWise(Matrix4fc other, Matrix4f dest)` Component-wise multiply `this` by `other` and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulComponentWise(Matrix4fc other, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mulLocal(Matrix4fc left, Matrix4f dest)` Pre-multiply this matrix by the supplied `left` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulLocal(Matrix4fc left, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mulLocalAffine(Matrix4fc left, Matrix4f dest)` Pre-multiply this matrix by the supplied `left` matrix, both of which are assumed to be `affine`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulLocalAffine(Matrix4fc left, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mulOrthoAffine(Matrix4fc view, Matrix4f dest)` Multiply `this` orthographic projection matrix by the supplied `affine` `view` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulOrthoAffine(Matrix4fc view, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mulPerspectiveAffine(Matrix4fc view, Matrix4f dest)` Multiply `this` symmetric perspective projection matrix by the supplied `affine` `view` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulPerspectiveAffine(Matrix4fc view, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mulPerspectiveAffine(Matrix4x3fc view, Matrix4f dest)` Multiply `this` symmetric perspective projection matrix by the supplied `view` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulPerspectiveAffine(Matrix4x3fc view, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`mulTranslationAffine(Matrix4fc right, Matrix4f dest)` Multiply this matrix, which is assumed to only contain a translation, by the supplied `right` matrix, which is assumed to be `affine`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`mulTranslationAffine(Matrix4fc right, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`normal(Matrix4f dest)` Compute a normal matrix from the upper left 3x3 submatrix of `this` and store it into the upper left 3x3 submatrix of `dest`.
`Matrix4f`	Matrix4f.`normal(Matrix4f dest)` Compute a normal matrix from the upper left 3x3 submatrix of `this` and store it into the upper left 3x3 submatrix of `dest`.
`Matrix4f`	Matrix4fc.`normalize3x3(Matrix4f dest)` Normalize the upper left 3x3 submatrix of this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`normalize3x3(Matrix4f dest)`
`Matrix4f`	Matrix4fc.`obliqueZ(float a, float b, Matrix4f dest)` Apply an oblique projection transformation to this matrix with the given values for `a` and `b` and store the result in `dest`.
`Matrix4f`	Matrix4f.`obliqueZ(float a, float b, Matrix4f dest)` Apply an oblique projection transformation to this matrix with the given values for `a` and `b` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`ortho(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`ortho(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`ortho(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`ortho(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`ortho2D(float left, float right, float bottom, float top, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`ortho2D(float left, float right, float bottom, float top, Matrix4f dest)` Apply an orthographic projection transformation for a right-handed coordinate system to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`ortho2DLH(float left, float right, float bottom, float top, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordinate system to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`ortho2DLH(float left, float right, float bottom, float top, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordinate system to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`orthoCrop(Matrix4fc view, Matrix4f dest)` Build an ortographic projection transformation that fits the view-projection transformation represented by `this` into the given affine `view` transformation.
`Matrix4f`	Matrix4f.`orthoCrop(Matrix4fc view, Matrix4f dest)` Build an ortographic projection transformation that fits the view-projection transformation represented by `this` into the given affine `view` transformation.
`Matrix4f`	Matrix4fc.`orthoLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordiante system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoLH(float left, float right, float bottom, float top, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordiante system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`orthoLH(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordiante system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoLH(float left, float right, float bottom, float top, float zNear, float zFar, Matrix4f dest)` Apply an orthographic projection transformation for a left-handed coordiante system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`orthoSymmetric(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoSymmetric(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`orthoSymmetric(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoSymmetric(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`orthoSymmetricLH(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoSymmetricLH(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`orthoSymmetricLH(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`orthoSymmetricLH(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric orthographic projection transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspective(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspective(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspective(float fovy, float aspect, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspective(float fovy, float aspect, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveFrustumSlice(float near, float far, Matrix4f dest)` Change the near and far clip plane distances of `this` perspective frustum transformation matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveFrustumSlice(float near, float far, Matrix4f dest)` Change the near and far clip plane distances of `this` perspective frustum transformation matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveLH(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveLH(float fovy, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a left-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveLH(float fovy, float aspect, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveLH(float fovy, float aspect, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a left-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar, Matrix4f dest)` Apply an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveOffCenter(float fovy, float offAngleX, float offAngleY, float aspect, float zNear, float zFar, Matrix4f dest)` Apply an asymmetric off-center perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveRect(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveRect(float width, float height, float zNear, float zFar, boolean zZeroToOne, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using the given NDC z range to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`perspectiveRect(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`perspectiveRect(float width, float height, float zNear, float zFar, Matrix4f dest)` Apply a symmetric perspective projection frustum transformation for a right-handed coordinate system using OpenGL's NDC z range of `[-1..+1]` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`pick(float x, float y, float width, float height, int[] viewport, Matrix4f dest)` Apply a picking transformation to this matrix using the given window coordinates `(x, y)` as the pick center and the given `(width, height)` as the size of the picking region in window coordinates, and store the result in `dest`.
`Matrix4f`	Matrix4f.`pick(float x, float y, float width, float height, int[] viewport, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`projectedGridRange(Matrix4fc projector, float sLower, float sUpper, Matrix4f dest)` Compute the range matrix for the Projected Grid transformation as described in chapter "2.4.2 Creating the range conversion matrix" of the paper Real-time water rendering - Introducing the projected grid concept based on the inverse of the view-projection matrix which is assumed to be `this`, and store that range matrix into `dest`.
`Matrix4f`	Matrix4f.`projectedGridRange(Matrix4fc projector, float sLower, float sUpper, Matrix4f dest)`
`static void`	Matrix4f.`projViewFromRectangle(Vector3f eye, Vector3f p, Vector3f x, Vector3f y, float nearFarDist, boolean zeroToOne, Matrix4f projDest, Matrix4f viewDest)` Create a view and projection matrix from a given `eye` position, a given bottom left corner position `p` of the near plane rectangle and the extents of the near plane rectangle along its local `x` and `y` axes, and store the resulting matrices in `projDest` and `viewDest`.
`Matrix4f`	Matrix4fc.`reflect(float nx, float ny, float nz, float px, float py, float pz, Matrix4f dest)` Apply a mirror/reflection transformation to this matrix that reflects about the given plane specified via the plane normal and a point on the plane, and store the result in `dest`.
`Matrix4f`	Matrix4f.`reflect(float nx, float ny, float nz, float px, float py, float pz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`reflect(float a, float b, float c, float d, Matrix4f dest)` Apply a mirror/reflection transformation to this matrix that reflects about the given plane specified via the equation `xa + yb + z*c + d = 0` and store the result in `dest`.
`Matrix4f`	Matrix4f.`reflect(float a, float b, float c, float d, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`reflect(Quaternionfc orientation, Vector3fc point, Matrix4f dest)` Apply a mirror/reflection transformation to this matrix that reflects about a plane specified via the plane orientation and a point on the plane, and store the result in `dest`.
`Matrix4f`	Matrix4f.`reflect(Quaternionfc orientation, Vector3fc point, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`reflect(Vector3fc normal, Vector3fc point, Matrix4f dest)` Apply a mirror/reflection transformation to this matrix that reflects about the given plane specified via the plane normal and a point on the plane, and store the result in `dest`.
`Matrix4f`	Matrix4f.`reflect(Vector3fc normal, Vector3fc point, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotate(AxisAngle4f axisAngle, Matrix4f dest)` Apply a rotation transformation, rotating about the given `AxisAngle4f` and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotate(AxisAngle4f axisAngle, Matrix4f dest)` Apply a rotation transformation, rotating about the given `AxisAngle4f` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotate(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotate(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotate(float angle, Vector3fc axis, Matrix4f dest)` Apply a rotation transformation, rotating the given radians about the specified axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotate(float angle, Vector3fc axis, Matrix4f dest)` Apply a rotation transformation, rotating the given radians about the specified axis and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotate(Quaternionfc quat, Matrix4f dest)` Apply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotate(Quaternionfc quat, Matrix4f dest)` Apply the rotation transformation of the given `Quaternionfc` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateAffine(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this `affine` matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffine(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this `affine` matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateAffine(Quaternionfc quat, Matrix4f dest)` Apply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this `affine` matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffine(Quaternionfc quat, Matrix4f dest)` Apply the rotation transformation of the given `Quaternionfc` to this `affine` matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateAffineXYZ(float angleX, float angleY, float angleZ, Matrix4f dest)` Apply rotation of `angleX` radians about the X axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleZ` radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffineXYZ(float angleX, float angleY, float angleZ, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateAffineYXZ(float angleY, float angleX, float angleZ, Matrix4f dest)` Apply rotation of `angleY` radians about the Y axis, followed by a rotation of `angleX` radians about the X axis and followed by a rotation of `angleZ` radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffineYXZ(float angleY, float angleX, float angleZ, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateAffineZYX(float angleZ, float angleY, float angleX, Matrix4f dest)` Apply rotation of `angleZ` radians about the Z axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleX` radians about the X axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAffineZYX(float angleZ, float angleY, float angleX, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateAround(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)` Apply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this matrix while using `(ox, oy, oz)` as the rotation origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAround(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateAroundAffine(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)` Apply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this `affine` matrix while using `(ox, oy, oz)` as the rotation origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAroundAffine(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateAroundLocal(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)` Pre-multiply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this matrix while using `(ox, oy, oz)` as the rotation origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateAroundLocal(Quaternionfc quat, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateLocal(float ang, float x, float y, float z, Matrix4f dest)` Pre-multiply a rotation to this matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocal(float ang, float x, float y, float z, Matrix4f dest)` Pre-multiply a rotation to this matrix by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateLocal(Quaternionfc quat, Matrix4f dest)` Pre-multiply the rotation - and possibly scaling - transformation of the given `Quaternionfc` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocal(Quaternionfc quat, Matrix4f dest)` Pre-multiply the rotation transformation of the given `Quaternionfc` to this matrix and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateLocalX(float ang, Matrix4f dest)` Pre-multiply a rotation around the X axis to this matrix by rotating the given amount of radians about the X axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocalX(float ang, Matrix4f dest)` Pre-multiply a rotation around the X axis to this matrix by rotating the given amount of radians about the X axis and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateLocalY(float ang, Matrix4f dest)` Pre-multiply a rotation around the Y axis to this matrix by rotating the given amount of radians about the Y axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocalY(float ang, Matrix4f dest)` Pre-multiply a rotation around the Y axis to this matrix by rotating the given amount of radians about the Y axis and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateLocalZ(float ang, Matrix4f dest)` Pre-multiply a rotation around the Z axis to this matrix by rotating the given amount of radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateLocalZ(float ang, Matrix4f dest)` Pre-multiply a rotation around the Z axis to this matrix by rotating the given amount of radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateTowards(float dirX, float dirY, float dirZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a model transformation to this matrix for a right-handed coordinate system, that aligns the local `+Z` axis with `(dirX, dirY, dirZ)` and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTowards(float dirX, float dirY, float dirZ, float upX, float upY, float upZ, Matrix4f dest)` Apply a model transformation to this matrix for a right-handed coordinate system, that aligns the local `+Z` axis with `(dirX, dirY, dirZ)` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateTowards(Vector3fc dir, Vector3fc up, Matrix4f dest)` Apply a model transformation to this matrix for a right-handed coordinate system, that aligns the local `+Z` axis with `dir` and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTowards(Vector3fc dir, Vector3fc up, Matrix4f dest)` Apply a model transformation to this matrix for a right-handed coordinate system, that aligns the local `+Z` axis with `dir` and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateTowardsXY(float dirX, float dirY, Matrix4f dest)` Apply rotation about the Z axis to align the local `+X` towards `(dirX, dirY)` and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTowardsXY(float dirX, float dirY, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateTranslation(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this matrix, which is assumed to only contain a translation, by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTranslation(float ang, float x, float y, float z, Matrix4f dest)` Apply rotation to this matrix, which is assumed to only contain a translation, by rotating the given amount of radians about the specified `(x, y, z)` axis and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateTranslation(Quaternionfc quat, Matrix4f dest)` Apply the rotation - and possibly scaling - ransformation of the given `Quaternionfc` to this matrix, which is assumed to only contain a translation, and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateTranslation(Quaternionfc quat, Matrix4f dest)` Apply the rotation transformation of the given `Quaternionfc` to this matrix, which is assumed to only contain a translation, and store the result in `dest`.
`Matrix4f`	Matrix4fc.`rotateX(float ang, Matrix4f dest)` Apply rotation about the X axis to this matrix by rotating the given amount of radians and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateX(float ang, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateXYZ(float angleX, float angleY, float angleZ, Matrix4f dest)` Apply rotation of `angleX` radians about the X axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleZ` radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateXYZ(float angleX, float angleY, float angleZ, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateY(float ang, Matrix4f dest)` Apply rotation about the Y axis to this matrix by rotating the given amount of radians and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateY(float ang, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateYXZ(float angleY, float angleX, float angleZ, Matrix4f dest)` Apply rotation of `angleY` radians about the Y axis, followed by a rotation of `angleX` radians about the X axis and followed by a rotation of `angleZ` radians about the Z axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateYXZ(float angleY, float angleX, float angleZ, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateZ(float ang, Matrix4f dest)` Apply rotation about the Z axis to this matrix by rotating the given amount of radians and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateZ(float ang, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`rotateZYX(float angleZ, float angleY, float angleX, Matrix4f dest)` Apply rotation of `angleZ` radians about the Z axis, followed by a rotation of `angleY` radians about the Y axis and followed by a rotation of `angleX` radians about the X axis and store the result in `dest`.
`Matrix4f`	Matrix4f.`rotateZYX(float angleZ, float angleY, float angleX, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scale(float x, float y, float z, Matrix4f dest)` Apply scaling to `this` matrix by scaling the base axes by the given x, y and z factors and store the result in `dest`.
`Matrix4f`	Matrix4f.`scale(float x, float y, float z, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scale(float xyz, Matrix4f dest)` Apply scaling to this matrix by uniformly scaling all base axes by the given `xyz` factor and store the result in `dest`.
`Matrix4f`	Matrix4f.`scale(float xyz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scale(Vector3fc xyz, Matrix4f dest)` Apply scaling to `this` matrix by scaling the base axes by the given `xyz.x`, `xyz.y` and `xyz.z` factors, respectively and store the result in `dest`.
`Matrix4f`	Matrix4f.`scale(Vector3fc xyz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scaleAround(float sx, float sy, float sz, float ox, float oy, float oz, Matrix4f dest)` Apply scaling to `this` matrix by scaling the base axes by the given sx, sy and sz factors while using `(ox, oy, oz)` as the scaling origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleAround(float sx, float sy, float sz, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scaleAround(float factor, float ox, float oy, float oz, Matrix4f dest)` Apply scaling to this matrix by scaling all three base axes by the given `factor` while using `(ox, oy, oz)` as the scaling origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleAround(float factor, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scaleAroundLocal(float sx, float sy, float sz, float ox, float oy, float oz, Matrix4f dest)` Pre-multiply scaling to `this` matrix by scaling the base axes by the given sx, sy and sz factors while using the given `(ox, oy, oz)` as the scaling origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleAroundLocal(float sx, float sy, float sz, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scaleAroundLocal(float factor, float ox, float oy, float oz, Matrix4f dest)` Pre-multiply scaling to this matrix by scaling all three base axes by the given `factor` while using `(ox, oy, oz)` as the scaling origin, and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleAroundLocal(float factor, float ox, float oy, float oz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scaleLocal(float x, float y, float z, Matrix4f dest)` Pre-multiply scaling to `this` matrix by scaling the base axes by the given x, y and z factors and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleLocal(float x, float y, float z, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scaleLocal(float xyz, Matrix4f dest)` Pre-multiply scaling to `this` matrix by scaling all base axes by the given `xyz` factor, and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleLocal(float xyz, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`scaleXY(float x, float y, Matrix4f dest)` Apply scaling to this matrix by by scaling the X axis by `x` and the Y axis by `y` and store the result in `dest`.
`Matrix4f`	Matrix4f.`scaleXY(float x, float y, Matrix4f dest)`
`Matrix4f`	Matrix4f.`set3x3(Matrix4f mat)` Set the upper left 3x3 submatrix of this `Matrix4f` to that of the given `Matrix4f` and don't change the other elements.
`Matrix4f`	Matrix4f.`set4x3(Matrix4f mat)` Set the upper 4x3 submatrix of this `Matrix4f` to the upper 4x3 submatrix of the given `Matrix4f` and don't change the other elements.
`Matrix4f`	Matrix4fc.`shadow(float lightX, float lightY, float lightZ, float lightW, float a, float b, float c, float d, Matrix4f dest)` Apply a projection transformation to this matrix that projects onto the plane specified via the general plane equation `xa + yb + z*c + d = 0` as if casting a shadow from a given light position/direction `(lightX, lightY, lightZ, lightW)` and store the result in `dest`.
`Matrix4f`	Matrix4f.`shadow(float lightX, float lightY, float lightZ, float lightW, float a, float b, float c, float d, Matrix4f dest)`
`Matrix4f`	Matrix4f.`shadow(float lightX, float lightY, float lightZ, float lightW, Matrix4f planeTransform)` Apply a projection transformation to this matrix that projects onto the plane with the general plane equation `y = 0` as if casting a shadow from a given light position/direction `(lightX, lightY, lightZ, lightW)`.
`Matrix4f`	Matrix4fc.`shadow(float lightX, float lightY, float lightZ, float lightW, Matrix4fc planeTransform, Matrix4f dest)` Apply a projection transformation to this matrix that projects onto the plane with the general plane equation `y = 0` as if casting a shadow from a given light position/direction `(lightX, lightY, lightZ, lightW)` and store the result in `dest`.
`Matrix4f`	Matrix4f.`shadow(float lightX, float lightY, float lightZ, float lightW, Matrix4fc planeTransform, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`shadow(Vector4f light, float a, float b, float c, float d, Matrix4f dest)` Apply a projection transformation to this matrix that projects onto the plane specified via the general plane equation `xa + yb + z*c + d = 0` as if casting a shadow from a given light position/direction `light` and store the result in `dest`.
`Matrix4f`	Matrix4f.`shadow(Vector4f light, float a, float b, float c, float d, Matrix4f dest)`
`Matrix4f`	Matrix4f.`shadow(Vector4f light, Matrix4f planeTransform)` Apply a projection transformation to this matrix that projects onto the plane with the general plane equation `y = 0` as if casting a shadow from a given light position/direction `light`.
`Matrix4f`	Matrix4fc.`shadow(Vector4f light, Matrix4fc planeTransform, Matrix4f dest)` Apply a projection transformation to this matrix that projects onto the plane with the general plane equation `y = 0` as if casting a shadow from a given light position/direction `light` and store the result in `dest`.
`Matrix4f`	Matrix4f.`shadow(Vector4f light, Matrix4fc planeTransform, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`sub(Matrix4fc subtrahend, Matrix4f dest)` Component-wise subtract `subtrahend` from `this` and store the result in `dest`.
`Matrix4f`	Matrix4f.`sub(Matrix4fc subtrahend, Matrix4f dest)`
`Matrix4f`	Matrix4f.`sub4x3(Matrix4f subtrahend)` Component-wise subtract the upper 4x3 submatrices of `subtrahend` from `this`.
`Matrix4f`	Matrix4fc.`sub4x3(Matrix4fc subtrahend, Matrix4f dest)` Component-wise subtract the upper 4x3 submatrices of `subtrahend` from `this` and store the result in `dest`.
`Matrix4f`	Matrix4f.`sub4x3(Matrix4fc subtrahend, Matrix4f dest)`
`Matrix4f`	Matrix4f.`swap(Matrix4f other)` Exchange the values of `this` matrix with the given `other` matrix.
`Matrix4f`	Matrix4fc.`translate(float x, float y, float z, Matrix4f dest)` Apply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translate(float x, float y, float z, Matrix4f dest)` Apply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4fc.`translate(Vector3fc offset, Matrix4f dest)` Apply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translate(Vector3fc offset, Matrix4f dest)` Apply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4fc.`translateLocal(float x, float y, float z, Matrix4f dest)` Pre-multiply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translateLocal(float x, float y, float z, Matrix4f dest)` Pre-multiply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4fc.`translateLocal(Vector3fc offset, Matrix4f dest)` Pre-multiply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translateLocal(Vector3fc offset, Matrix4f dest)` Pre-multiply a translation to this matrix by translating by the given number of units in x, y and z and store the result in `dest`.
`Matrix4f`	Matrix4f.`translationRotateScaleMulAffine(float tx, float ty, float tz, float qx, float qy, float qz, float qw, float sx, float sy, float sz, Matrix4f m)` Set `this` matrix to `T * R * S * M`, where `T` is a translation by the given `(tx, ty, tz)`, `R` is a rotation - and possibly scaling - transformation specified by the quaternion `(qx, qy, qz, qw)`, `S` is a scaling transformation which scales the three axes x, y and z by `(sx, sy, sz)` and `M` is an `affine` matrix.
`Matrix4f`	Matrix4f.`translationRotateScaleMulAffine(Vector3fc translation, Quaternionfc quat, Vector3fc scale, Matrix4f m)` Set `this` matrix to `T * R * S * M`, where `T` is the given `translation`, `R` is a rotation - and possibly scaling - transformation specified by the given quaternion, `S` is a scaling transformation which scales the axes by `scale` and `M` is an `affine` matrix.
`Matrix4f`	Matrix4fc.`transpose(Matrix4f dest)` Transpose this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`transpose(Matrix4f dest)`
`Matrix4f`	Matrix4fc.`transpose3x3(Matrix4f dest)` Transpose only the upper left 3x3 submatrix of this matrix and store the result in `dest`.
`Matrix4f`	Matrix4f.`transpose3x3(Matrix4f dest)`
`Matrix4f`	Matrix4fc.`withLookAtUp(float upX, float upY, float upZ, Matrix4f dest)` Apply a transformation to this matrix to ensure that the local Y axis (as obtained by `Matrix4fc.positiveY(Vector3f)`) will be coplanar to the plane spanned by the local Z axis (as obtained by `Matrix4fc.positiveZ(Vector3f)`) and the given vector `(upX, upY, upZ)`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`withLookAtUp(float upX, float upY, float upZ, Matrix4f dest)`
`Matrix4f`	Matrix4fc.`withLookAtUp(Vector3fc up, Matrix4f dest)` Apply a transformation to this matrix to ensure that the local Y axis (as obtained by `Matrix4fc.positiveY(Vector3f)`) will be coplanar to the plane spanned by the local Z axis (as obtained by `Matrix4fc.positiveZ(Vector3f)`) and the given vector `up`, and store the result in `dest`.
`Matrix4f`	Matrix4f.`withLookAtUp(Vector3fc up, Matrix4f dest)`

Uses of Matrix4f in org.joml.internal

Methods in org.joml.internal with parameters of type Matrix4f
Modifier and Type	Method and Description
`abstract void`	MemUtil.`copy(float[] arr, int off, Matrix4f dest)`
`void`	MemUtil.MemUtilNIO.`copy(float[] arr, int off, Matrix4f dest)`
`abstract void`	MemUtil.`copy(Matrix3f src, Matrix4f dest)`
`void`	MemUtil.MemUtilNIO.`copy(Matrix3f src, Matrix4f dest)`
`abstract void`	MemUtil.`copy(Matrix4f src, float[] dest, int off)`
`void`	MemUtil.MemUtilNIO.`copy(Matrix4f src, float[] dest, int off)`
`abstract void`	MemUtil.`copy(Matrix4f src, Matrix3f dest)`
`void`	MemUtil.MemUtilNIO.`copy(Matrix4f src, Matrix3f dest)`
`abstract void`	MemUtil.`copy(Matrix4f src, Matrix4f dest)`
`void`	MemUtil.MemUtilNIO.`copy(Matrix4f src, Matrix4f dest)`
`abstract void`	MemUtil.`copy(Matrix4f src, Matrix4x3f dest)`
`void`	MemUtil.MemUtilNIO.`copy(Matrix4f src, Matrix4x3f dest)`
`abstract void`	MemUtil.`copy(Matrix4x3f src, Matrix4f dest)`
`void`	MemUtil.MemUtilNIO.`copy(Matrix4x3f src, Matrix4f dest)`
`abstract void`	MemUtil.`copy3x3(Matrix3f src, Matrix4f dest)`
`void`	MemUtil.MemUtilNIO.`copy3x3(Matrix3f src, Matrix4f dest)`
`abstract void`	MemUtil.`copy3x3(Matrix4f src, Matrix4f dest)`
`void`	MemUtil.MemUtilNIO.`copy3x3(Matrix4f src, Matrix4f dest)`
`abstract void`	MemUtil.`copy4x3(Matrix4f src, Matrix4f dest)`
`void`	MemUtil.MemUtilNIO.`copy4x3(Matrix4f src, Matrix4f dest)`
`abstract void`	MemUtil.`copy4x3(Matrix4x3f src, Matrix4f dest)`
`void`	MemUtil.MemUtilNIO.`copy4x3(Matrix4x3f src, Matrix4f dest)`
`abstract void`	MemUtil.`get(Matrix4f m, int offset, ByteBuffer src)`
`void`	MemUtil.MemUtilNIO.`get(Matrix4f m, int offset, ByteBuffer src)`
`abstract void`	MemUtil.`get(Matrix4f m, int offset, FloatBuffer src)`
`void`	MemUtil.MemUtilNIO.`get(Matrix4f m, int offset, FloatBuffer src)`
`abstract void`	MemUtil.`getColumn0(Matrix4f dest, Vector4f src)`
`void`	MemUtil.MemUtilNIO.`getColumn0(Matrix4f dest, Vector4f src)`
`abstract void`	MemUtil.`getColumn1(Matrix4f dest, Vector4f src)`
`void`	MemUtil.MemUtilNIO.`getColumn1(Matrix4f dest, Vector4f src)`
`abstract void`	MemUtil.`getColumn2(Matrix4f dest, Vector4f src)`
`void`	MemUtil.MemUtilNIO.`getColumn2(Matrix4f dest, Vector4f src)`
`abstract void`	MemUtil.`getColumn3(Matrix4f dest, Vector4f src)`
`void`	MemUtil.MemUtilNIO.`getColumn3(Matrix4f dest, Vector4f src)`
`abstract void`	MemUtil.`identity(Matrix4f dest)`
`void`	MemUtil.MemUtilNIO.`identity(Matrix4f dest)`
`abstract void`	MemUtil.`put(Matrix4f m, int offset, ByteBuffer dest)`
`void`	MemUtil.MemUtilNIO.`put(Matrix4f m, int offset, ByteBuffer dest)`
`abstract void`	MemUtil.`put(Matrix4f m, int offset, FloatBuffer dest)`
`void`	MemUtil.MemUtilNIO.`put(Matrix4f m, int offset, FloatBuffer dest)`
`void`	MemUtil.MemUtilNIO.`put0(Matrix4f m, ByteBuffer dest)`
`void`	MemUtil.MemUtilNIO.`put0(Matrix4f m, FloatBuffer dest)`
`void`	MemUtil.MemUtilNIO.`put4x3_0(Matrix4f m, ByteBuffer dest)`
`void`	MemUtil.MemUtilNIO.`put4x3_0(Matrix4f m, FloatBuffer dest)`
`void`	MemUtil.MemUtilNIO.`put4x3_N(Matrix4f m, int offset, FloatBuffer dest)`
`abstract void`	MemUtil.`put4x3(Matrix4f m, int offset, ByteBuffer dest)`
`void`	MemUtil.MemUtilNIO.`put4x3(Matrix4f m, int offset, ByteBuffer dest)`
`abstract void`	MemUtil.`put4x3(Matrix4f m, int offset, FloatBuffer dest)`
`void`	MemUtil.MemUtilNIO.`put4x3(Matrix4f m, int offset, FloatBuffer dest)`
`abstract void`	MemUtil.`put4x3Transposed(Matrix4f m, int offset, ByteBuffer dest)`
`void`	MemUtil.MemUtilNIO.`put4x3Transposed(Matrix4f m, int offset, ByteBuffer dest)`
`abstract void`	MemUtil.`put4x3Transposed(Matrix4f m, int offset, FloatBuffer dest)`
`void`	MemUtil.MemUtilNIO.`put4x3Transposed(Matrix4f m, int offset, FloatBuffer dest)`
`abstract void`	MemUtil.`putColumn0(Matrix4f src, Vector3f dest)`
`void`	MemUtil.MemUtilNIO.`putColumn0(Matrix4f src, Vector3f dest)`
`abstract void`	MemUtil.`putColumn0(Matrix4f src, Vector4f dest)`
`void`	MemUtil.MemUtilNIO.`putColumn0(Matrix4f src, Vector4f dest)`
`abstract void`	MemUtil.`putColumn1(Matrix4f src, Vector3f dest)`
`void`	MemUtil.MemUtilNIO.`putColumn1(Matrix4f src, Vector3f dest)`
`abstract void`	MemUtil.`putColumn1(Matrix4f src, Vector4f dest)`
`void`	MemUtil.MemUtilNIO.`putColumn1(Matrix4f src, Vector4f dest)`
`abstract void`	MemUtil.`putColumn2(Matrix4f src, Vector3f dest)`
`void`	MemUtil.MemUtilNIO.`putColumn2(Matrix4f src, Vector3f dest)`
`abstract void`	MemUtil.`putColumn2(Matrix4f src, Vector4f dest)`
`void`	MemUtil.MemUtilNIO.`putColumn2(Matrix4f src, Vector4f dest)`
`abstract void`	MemUtil.`putColumn3(Matrix4f src, Vector3f dest)`
`void`	MemUtil.MemUtilNIO.`putColumn3(Matrix4f src, Vector3f dest)`
`abstract void`	MemUtil.`putColumn3(Matrix4f src, Vector4f dest)`
`void`	MemUtil.MemUtilNIO.`putColumn3(Matrix4f src, Vector4f dest)`
`void`	MemUtil.MemUtilNIO.`putN(Matrix4f m, int offset, FloatBuffer dest)`
`abstract void`	MemUtil.`putTransposed(Matrix4f m, int offset, ByteBuffer dest)`
`void`	MemUtil.MemUtilNIO.`putTransposed(Matrix4f m, int offset, ByteBuffer dest)`
`abstract void`	MemUtil.`putTransposed(Matrix4f m, int offset, FloatBuffer dest)`
`void`	MemUtil.MemUtilNIO.`putTransposed(Matrix4f m, int offset, FloatBuffer dest)`
`abstract void`	MemUtil.`set(Matrix4f dest, Vector4f col0, Vector4f col1, Vector4f col2, Vector4f col3)`
`void`	MemUtil.MemUtilNIO.`set(Matrix4f m, Vector4f col0, Vector4f col1, Vector4f col2, Vector4f col3)`
`abstract void`	MemUtil.`swap(Matrix4f m1, Matrix4f m2)`
`void`	MemUtil.MemUtilNIO.`swap(Matrix4f m1, Matrix4f m2)`
`abstract void`	MemUtil.`zero(Matrix4f dest)`
`void`	MemUtil.MemUtilNIO.`zero(Matrix4f dest)`

Uses of Classorg.joml.Matrix4f

Uses of Matrix4f in org.joml

Uses of Matrix4f in org.joml.internal

Uses of Class
org.joml.Matrix4f