4D Matrix. Values are stored in column major order.

Constructors

Matrix4(double arg0, double arg1, double arg2, double arg3, double arg4, double arg5, double arg6, double arg7, double arg8, double arg9, double arg10, double arg11, double arg12, double arg13, double arg14, double arg15)
Constructs a new mat4.
factory
Matrix4.columns(Vector4 arg0, Vector4 arg1, Vector4 arg2, Vector4 arg3)
Constructs a new mat4 from columns.
factory
Matrix4.compose(Vector3 translation, Quaternion rotation, Vector3 scale)
Constructs Matrix4 from translation, rotation and scale.
factory
Matrix4.copy(Matrix4 other)
Copies values from other.
factory
Matrix4.diagonal3(Vector3 scale)
Scale matrix.
factory
Matrix4.diagonal3Values(double x, double y, double z)
Scale matrix.
factory
Matrix4.fromBuffer(ByteBuffer buffer, int offset)
Constructs Matrix4 with a storage that views given buffer starting at offset. offset has to be multiple of Float64List.BYTES_PER_ELEMENT.
Matrix4.fromFloat64List(Float64List _m4storage)
Constructs Matrix4 with given Float64List as storage.
Matrix4.fromList(List<double> values)
New matrix from values.
factory
Matrix4.identity()
Identity matrix.
factory
Matrix4.inverted(Matrix4 other)
Constructs a matrix that is the inverse of other.
factory
Matrix4.outer(Vector4 u, Vector4 v)
Outer product of u and v.
factory
Matrix4.rotationX(double radians)
Rotation of radians_ around X.
factory
Matrix4.rotationY(double radians)
Rotation of radians_ around Y.
factory
Matrix4.rotationZ(double radians)
Rotation of radians_ around Z.
factory
Matrix4.skew(double alpha, double beta)
Skew matrix around X axis (alpha) and Y axis (beta).
factory
Matrix4.skewX(double alpha)
Skew matrix around X axis
factory
Matrix4.skewY(double beta)
Skew matrix around Y axis.
factory
Matrix4.translation(Vector3 translation)
Translation matrix.
factory
Matrix4.translationValues(double x, double y, double z)
Translation matrix.
factory
Matrix4.zero()
Zero matrix.

Properties

dimension int
Dimension of the matrix.
read-only
forward Vector3
read-only
hashCode int
The hash code for this object. [...]
@override, read-only
read-only
row0 Vector4 arg
Returns row 0
read / write
row1 Vector4 arg
Returns row 1
read / write
row2 Vector4 arg
Returns row 2
read / write
row3 Vector4 arg
Returns row 3
read / write
storage Float64List
The components of the matrix.
read-only
up Vector3
read-only
runtimeType Type
A representation of the runtime type of the object.
read-only, inherited

Methods

absolute() Matrix4
Returns the component wise absolute value of this.
absoluteError(Matrix4 correct) double
Returns absolute error between this and correct
absoluteRotate(Vector3 arg) Vector3
Rotates arg by the absolute rotation of this Returns arg. Primarily used by AABB transformation code.
add(Matrix4 o) → void
Adds o to this.
applyToVector3Array(List<double> array, [ int offset = 0 ]) List<double>
Multiply this to each set of xyz values in array starting at offset.
clone() Matrix4
Clone matrix.
copyFromArray(List<double> array, [ int offset = 0 ]) → void
Copies elements from array into this starting at offset.
copyInto(Matrix4 arg) Matrix4
Copy into arg.
copyIntoArray(List<num> array, [ int offset = 0 ]) → void
Copies this into array starting at offset.
copyInverse(Matrix4 arg) double
Set this matrix to be the inverse of arg
copyRotation(Matrix3 rotation) → void
Copies the rotation matrix from this homogeneous transformation matrix into rotation.
decompose(Vector3 translation, Quaternion rotation, Vector3 scale) → void
Decomposes this into translation, rotation and scale components.
determinant() double
Returns the determinant of this matrix.
dotColumn(int j, Vector4 v) double
Returns the dot product of column j and v.
dotRow(int i, Vector4 v) double
Returns the dot product of row i and v.
entry(int row, int col) double
Value at row, col.
getColumn(int column) Vector4
Gets the column of the matrix
getMaxScaleOnAxis() double
Returns the max scale value of the 3 axes.
getNormalMatrix() Matrix3
Returns the normal matrix from this homogeneous transformation matrix. The normal matrix is the transpose of the inverse of the top-left 3x3 part of this 4x4 matrix.
getRotation() Matrix3
Returns the rotation matrix from this homogeneous transformation matrix.
getRow(int row) Vector4
Gets the row of the matrix
getTranslation() Vector3
Returns the translation vector from this homogeneous transformation matrix.
index(int row, int col) int
Return index in storage for row, col value.
infinityNorm() double
Returns infinity norm of the matrix. Used for numerical analysis.
invert() double
Invert this.
invertRotation() double
isIdentity() bool
Is this the identity matrix?
isZero() bool
Is this the zero matrix?
leftTranslate(x, [ double y = 0.0, double z = 0.0 ]) → void
Multiply this by a translation from the left. The translation can be specified with a Vector3, Vector4, or x, y, z.
multiplied(Matrix4 arg) Matrix4
Multiply a copy of this with arg.
multiply(Matrix4 arg) → void
Multiply this by arg.
multiplyTranspose(Matrix4 arg) → void
Multiply this with a transposed arg.
negate() → void
Negate this.
perspectiveTransform(Vector3 arg) Vector3
Transform arg of type Vector3 using the perspective transformation defined by this.
relativeError(Matrix4 correct) double
Returns relative error between this and correct
rotate(Vector3 axis, double angle) → void
Rotate this angle radians around axis
rotate3(Vector3 arg) Vector3
Rotate arg of type Vector3 using the rotation defined by this.
rotated3(Vector3 arg, [ Vector3 out ]) Vector3
Rotate a copy of arg of type Vector3 using the rotation defined by this. If a out parameter is supplied, the copy is stored in out.
rotateX(double angle) → void
Rotate this angle radians around X
rotateY(double angle) → void
Rotate this matrix angle radians around Y
rotateZ(double angle) → void
Rotate this matrix angle radians around Z
scale(x, [ double y, double z ]) → void
Scale this matrix by a Vector3, Vector4, or x,y,z
scaleAdjoint(double scale) → void
Converts into Adjugate matrix and scales by scale
scaled(x, [ double y = null, double z = null ]) Matrix4
Create a copy of this scaled by a Vector3, Vector4 or x,y, and z.
setColumn(int column, Vector4 arg) → void
Assigns the column of the matrix arg
setColumns(Vector4 arg0, Vector4 arg1, Vector4 arg2, Vector4 arg3) → void
Sets the entire matrix to the column values.
setDiagonal(Vector4 arg) → void
Sets the diagonal of the matrix to be arg.
setEntry(int row, int col, double v) → void
Set value at row, col to be v.
setFrom(Matrix4 arg) → void
Sets the entire matrix to the matrix in arg.
setFromTranslationRotation(Vector3 arg0, Quaternion arg1) → void
Sets the matrix from translation arg0 and rotation arg1.
setFromTranslationRotationScale(Vector3 translation, Quaternion rotation, Vector3 scale) → void
Sets the matrix from translation, rotation and scale.
setIdentity() → void
Makes this into the identity matrix.
setOuter(Vector4 u, Vector4 v) → void
setRotation(Matrix3 r) → void
Sets the rotation matrix in this homogeneous transformation matrix.
setRotationX(double radians) → void
Sets the upper 3x3 to a rotation of radians around X
setRotationY(double radians) → void
Sets the upper 3x3 to a rotation of radians around Y
setRotationZ(double radians) → void
Sets the upper 3x3 to a rotation of radians around Z
setRow(int row, Vector4 arg) → void
Assigns the row of the matrix arg
setTranslation(Vector3 t) → void
Sets the translation vector in this homogeneous transformation matrix.
setTranslationRaw(double x, double y, double z) → void
Sets the translation vector in this homogeneous transformation matrix.
setUpper2x2(Matrix2 arg) → void
Sets the upper 2x2 of the matrix to be arg.
setValues(double arg0, double arg1, double arg2, double arg3, double arg4, double arg5, double arg6, double arg7, double arg8, double arg9, double arg10, double arg11, double arg12, double arg13, double arg14, double arg15) → void
Sets the matrix with specified values.
setZero() → void
Zeros this.
splatDiagonal(double arg) → void
Sets the diagonal to arg.
sub(Matrix4 o) → void
Subtracts o from this.
toString() String
Returns a printable string
trace() double
Returns the trace of the matrix. The trace of a matrix is the sum of the diagonal entries.
transform(Vector4 arg) Vector4
Transform arg of type Vector4 using the transformation defined by this.
transform3(Vector3 arg) Vector3
Transform arg of type Vector3 using the transformation defined by this.
transformed(Vector4 arg, [ Vector4 out ]) Vector4
Transform a copy of arg of type Vector4 using the transformation defined by this. If a out parameter is supplied, the copy is stored in out.
transformed3(Vector3 arg, [ Vector3 out ]) Vector3
Transform a copy of arg of type Vector3 using the transformation defined by this. If a out parameter is supplied, the copy is stored in out.
translate(x, [ double y = 0.0, double z = 0.0 ]) → void
Translate this matrix by a Vector3, Vector4, or x,y,z
transpose() → void
transposed() Matrix4
Returns the tranpose of this.
transposeMultiply(Matrix4 arg) → void
Multiply a transposed this with arg.
transposeRotation() → void
Transposes just the upper 3x3 rotation matrix.
noSuchMethod(Invocation invocation) → dynamic
Invoked when a non-existent method or property is accessed. [...]
inherited

Operators

operator *(arg) → dynamic
Returns a new vector or matrix by multiplying this with arg.
operator +(Matrix4 arg) Matrix4
Returns new matrix after component wise this + arg
operator -(Matrix4 arg) Matrix4
Returns new matrix after component wise this - arg
operator ==(Object other) bool
Check if two matrices are the same.
operator [](int i) double
Access the element of the matrix at the index i.
operator []=(int i, double v) → void
Set the element of the matrix at the index i.
operator unary-() Matrix4
Returns new matrix -this

Static Methods

solve(Matrix4 A, Vector4 x, Vector4 b) → void
Solve A * x = b.
solve2(Matrix4 A, Vector2 x, Vector2 b) → void
Solve A * x = b.
solve3(Matrix4 A, Vector3 x, Vector3 b) → void
Solve A * x = b.