/// <summary>
/// Constructs this matrix from a imat2. Non-overwritten fields are from an Identity matrix.
/// </summary>
public imat2(imat2 m)
{
this.m00 = m.m00;
this.m01 = m.m01;
this.m10 = m.m10;
this.m11 = m.m11;
}
/// <summary>
/// Constructs this matrix from a imat2. Non-overwritten fields are from an Identity matrix.
/// </summary>
public imat3x2(imat2 m)
{
this.m00 = m.m00;
this.m01 = m.m01;
this.m10 = m.m10;
this.m11 = m.m11;
this.m20 = 0;
this.m21 = 0;
}
/// <summary>
/// Constructs this matrix from a imat2. Non-overwritten fields are from an Identity matrix.
/// </summary>
public imat2x3(imat2 m)
{
this.m00 = m.m00;
this.m01 = m.m01;
this.m02 = 0;
this.m10 = m.m10;
this.m11 = m.m11;
this.m12 = 0;
}
/// <summary>
/// Constructs this matrix from a imat2. Non-overwritten fields are from an Identity matrix.
/// </summary>
public imat3(imat2 m)
{
this.m00 = m.m00;
this.m01 = m.m01;
this.m02 = 0;
this.m10 = m.m10;
this.m11 = m.m11;
this.m12 = 0;
this.m20 = 0;
this.m21 = 0;
this.m22 = 1;
}
/// <summary>
/// Constructs this matrix from a imat2. Non-overwritten fields are from an Identity matrix.
/// </summary>
public imat4x3(imat2 m)
{
this.m00 = m.m00;
this.m01 = m.m01;
this.m02 = 0;
this.m10 = m.m10;
this.m11 = m.m11;
this.m12 = 0;
this.m20 = 0;
this.m21 = 0;
this.m22 = 1;
this.m30 = 0;
this.m31 = 0;
this.m32 = 0;
}
/// <summary>
/// Constructs this matrix from a imat2. Non-overwritten fields are from an Identity matrix.
/// </summary>
public imat3x4(imat2 m)
{
this.m00 = m.m00;
this.m01 = m.m01;
this.m02 = 0;
this.m03 = 0;
this.m10 = m.m10;
this.m11 = m.m11;
this.m12 = 0;
this.m13 = 0;
this.m20 = 0;
this.m21 = 0;
this.m22 = 1;
this.m23 = 0;
}
/// <summary> /// Returns an enumerator that iterates through all fields. /// </summary> public static IEnumerator <int> GetEnumerator(imat2 m) => m.GetEnumerator();
/// <summary> /// Creates a 1D array with all values (internal order) /// </summary> public static int[] Values1D(imat2 m) => m.Values1D;
/// <summary> /// Creates a 2D array with all values (address: Values[x, y]) /// </summary> public static int[,] Values(imat2 m) => m.Values;
/// <summary> /// Executes a component-wise - (subtract). /// </summary> public static imat2 CompSub(imat2 A, imat2 B) => new imat2(A.m00 - B.m00, A.m01 - B.m01, A.m10 - B.m10, A.m11 - B.m11);
/// <summary> /// Executes a component-wise + (add). /// </summary> public static imat2 CompAdd(imat2 A, imat2 B) => new imat2(A.m00 + B.m00, A.m01 + B.m01, A.m10 + B.m10, A.m11 + B.m11);
/// <summary> /// Executes a component-wise / (divide). /// </summary> public static imat2 CompDiv(imat2 A, imat2 B) => new imat2(A.m00 / B.m00, A.m01 / B.m01, A.m10 / B.m10, A.m11 / B.m11);
/// <summary> /// Executes a component-wise * (multiply). /// </summary> public static imat2 CompMul(imat2 A, imat2 B) => new imat2(A.m00 * B.m00, A.m01 * B.m01, A.m10 * B.m10, A.m11 * B.m11);
/// <summary> /// Returns true iff this equals rhs component-wise. /// </summary> public bool Equals(imat2 rhs) => ((m00.Equals(rhs.m00) && m01.Equals(rhs.m01)) && (m10.Equals(rhs.m10) && m11.Equals(rhs.m11)));