// Copyright 2013 The Closure Library Authors. All Rights Reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS-IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. ////////////////////////// NOTE ABOUT EDITING THIS FILE /////////////////////// // // // Any edits to this file must be applied to mat3d.js by running: // // swap_type.sh mat3f.js > mat3d.js // // // ////////////////////////// NOTE ABOUT EDITING THIS FILE /////////////////////// /** * @fileoverview Provides functions for operating on 3x3 float (32bit) * matrices. The matrices are stored in column-major order. * * The last parameter will typically be the output object and an object * can be both an input and output parameter to all methods except where * noted. * * See the README for notes about the design and structure of the API * (especially related to performance). * */ goog.provide('goog.vec.mat3f'); goog.provide('goog.vec.mat3f.Type'); goog.require('goog.vec'); goog.require('goog.vec.vec3f.Type'); /** @typedef {goog.vec.Float32} */ goog.vec.mat3f.Type; /** * Creates a mat3f with all elements initialized to zero. * * @return {!goog.vec.mat3f.Type} The new mat3f. */ goog.vec.mat3f.create = function() { return new Float32Array(9); }; /** * Creates a mat3f identity matrix. * * @return {!goog.vec.mat3f.Type} The new mat3f. */ goog.vec.mat3f.createIdentity = function() { var mat = goog.vec.mat3f.create(); mat[0] = mat[4] = mat[8] = 1; return mat; }; /** * Initializes the matrix from the set of values. Note the values supplied are * in column major order. * * @param {!goog.vec.mat3f.Type} mat The matrix to receive the * values. * @param {number} v00 The values at (0, 0). * @param {number} v10 The values at (1, 0). * @param {number} v20 The values at (2, 0). * @param {number} v01 The values at (0, 1). * @param {number} v11 The values at (1, 1). * @param {number} v21 The values at (2, 1). * @param {number} v02 The values at (0, 2). * @param {number} v12 The values at (1, 2). * @param {number} v22 The values at (2, 2). * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained together. */ goog.vec.mat3f.setFromValues = function( mat, v00, v10, v20, v01, v11, v21, v02, v12, v22) { mat[0] = v00; mat[1] = v10; mat[2] = v20; mat[3] = v01; mat[4] = v11; mat[5] = v21; mat[6] = v02; mat[7] = v12; mat[8] = v22; return mat; }; /** * Initializes mat3f mat from mat3f src. * * @param {!goog.vec.mat3f.Type} mat The destination matrix. * @param {!goog.vec.mat3f.Type} src The source matrix. * @return {!goog.vec.mat3f.Type} Return mat so that operations can be * chained together. */ goog.vec.mat3f.setFromMat3f = function(mat, src) { mat[0] = src[0]; mat[1] = src[1]; mat[2] = src[2]; mat[3] = src[3]; mat[4] = src[4]; mat[5] = src[5]; mat[6] = src[6]; mat[7] = src[7]; mat[8] = src[8]; return mat; }; /** * Initializes mat3f mat from mat3d src (typed as a Float64Array to * avoid circular goog.requires). * * @param {!goog.vec.mat3f.Type} mat The destination matrix. * @param {Float64Array} src The source matrix. * @return {!goog.vec.mat3f.Type} Return mat so that operations can be * chained together. */ goog.vec.mat3f.setFromMat3d = function(mat, src) { mat[0] = src[0]; mat[1] = src[1]; mat[2] = src[2]; mat[3] = src[3]; mat[4] = src[4]; mat[5] = src[5]; mat[6] = src[6]; mat[7] = src[7]; mat[8] = src[8]; return mat; }; /** * Initializes mat3f mat from Array src. * * @param {!goog.vec.mat3f.Type} mat The destination matrix. * @param {Array} src The source matrix. * @return {!goog.vec.mat3f.Type} Return mat so that operations can be * chained together. */ goog.vec.mat3f.setFromArray = function(mat, src) { mat[0] = src[0]; mat[1] = src[1]; mat[2] = src[2]; mat[3] = src[3]; mat[4] = src[4]; mat[5] = src[5]; mat[6] = src[6]; mat[7] = src[7]; mat[8] = src[8]; return mat; }; /** * Retrieves the element at the requested row and column. * * @param {!goog.vec.mat3f.Type} mat The matrix containing the value to * retrieve. * @param {number} row The row index. * @param {number} column The column index. * @return {number} The element value at the requested row, column indices. */ goog.vec.mat3f.getElement = function(mat, row, column) { return mat[row + column * 3]; }; /** * Sets the element at the requested row and column. * * @param {!goog.vec.mat3f.Type} mat The matrix containing the value to * retrieve. * @param {number} row The row index. * @param {number} column The column index. * @param {number} value The value to set at the requested row, column. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained together. */ goog.vec.mat3f.setElement = function(mat, row, column, value) { mat[row + column * 3] = value; return mat; }; /** * Sets the diagonal values of the matrix from the given values. * * @param {!goog.vec.mat3f.Type} mat The matrix to receive the values. * @param {number} v00 The values for (0, 0). * @param {number} v11 The values for (1, 1). * @param {number} v22 The values for (2, 2). * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained together. */ goog.vec.mat3f.setDiagonalValues = function(mat, v00, v11, v22) { mat[0] = v00; mat[4] = v11; mat[8] = v22; return mat; }; /** * Sets the diagonal values of the matrix from the given vector. * * @param {!goog.vec.mat3f.Type} mat The matrix to receive the values. * @param {!goog.vec.vec3f.Type} vec The vector containing the values. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained together. */ goog.vec.mat3f.setDiagonal = function(mat, vec) { mat[0] = vec[0]; mat[4] = vec[1]; mat[8] = vec[2]; return mat; }; /** * Sets the specified column with the supplied values. * * @param {!goog.vec.mat3f.Type} mat The matrix to receive the values. * @param {number} column The column index to set the values on. * @param {number} v0 The value for row 0. * @param {number} v1 The value for row 1. * @param {number} v2 The value for row 2. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained together. */ goog.vec.mat3f.setColumnValues = function(mat, column, v0, v1, v2) { var i = column * 3; mat[i] = v0; mat[i + 1] = v1; mat[i + 2] = v2; return mat; }; /** * Sets the specified column with the value from the supplied array. * * @param {!goog.vec.mat3f.Type} mat The matrix to receive the values. * @param {number} column The column index to set the values on. * @param {!goog.vec.vec3f.Type} vec The vector elements for the column. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained together. */ goog.vec.mat3f.setColumn = function(mat, column, vec) { var i = column * 3; mat[i] = vec[0]; mat[i + 1] = vec[1]; mat[i + 2] = vec[2]; return mat; }; /** * Retrieves the specified column from the matrix into the given vector * array. * * @param {!goog.vec.mat3f.Type} mat The matrix supplying the values. * @param {number} column The column to get the values from. * @param {!goog.vec.vec3f.Type} vec The vector elements to receive the * column. * @return {!goog.vec.vec3f.Type} return vec so that operations can be * chained together. */ goog.vec.mat3f.getColumn = function(mat, column, vec) { var i = column * 3; vec[0] = mat[i]; vec[1] = mat[i + 1]; vec[2] = mat[i + 2]; return vec; }; /** * Sets the columns of the matrix from the set of vector elements. * * @param {!goog.vec.mat3f.Type} mat The matrix to receive the values. * @param {!goog.vec.vec3f.Type} vec0 The values for column 0. * @param {!goog.vec.vec3f.Type} vec1 The values for column 1. * @param {!goog.vec.vec3f.Type} vec2 The values for column 2. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained together. */ goog.vec.mat3f.setColumns = function(mat, vec0, vec1, vec2) { goog.vec.mat3f.setColumn(mat, 0, vec0); goog.vec.mat3f.setColumn(mat, 1, vec1); goog.vec.mat3f.setColumn(mat, 2, vec2); return /** @type {!goog.vec.mat3f.Type} */ (mat); }; /** * Retrieves the column values from the given matrix into the given vector * elements. * * @param {!goog.vec.mat3f.Type} mat The matrix supplying the columns. * @param {!goog.vec.vec3f.Type} vec0 The vector to receive column 0. * @param {!goog.vec.vec3f.Type} vec1 The vector to receive column 1. * @param {!goog.vec.vec3f.Type} vec2 The vector to receive column 2. */ goog.vec.mat3f.getColumns = function(mat, vec0, vec1, vec2) { goog.vec.mat3f.getColumn(mat, 0, vec0); goog.vec.mat3f.getColumn(mat, 1, vec1); goog.vec.mat3f.getColumn(mat, 2, vec2); }; /** * Sets the row values from the supplied values. * * @param {!goog.vec.mat3f.Type} mat The matrix to receive the values. * @param {number} row The index of the row to receive the values. * @param {number} v0 The value for column 0. * @param {number} v1 The value for column 1. * @param {number} v2 The value for column 2. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained together. */ goog.vec.mat3f.setRowValues = function(mat, row, v0, v1, v2) { mat[row] = v0; mat[row + 3] = v1; mat[row + 6] = v2; return mat; }; /** * Sets the row values from the supplied vector. * * @param {!goog.vec.mat3f.Type} mat The matrix to receive the row values. * @param {number} row The index of the row. * @param {!goog.vec.vec3f.Type} vec The vector containing the values. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained together. */ goog.vec.mat3f.setRow = function(mat, row, vec) { mat[row] = vec[0]; mat[row + 3] = vec[1]; mat[row + 6] = vec[2]; return mat; }; /** * Retrieves the row values into the given vector. * * @param {!goog.vec.mat3f.Type} mat The matrix supplying the values. * @param {number} row The index of the row supplying the values. * @param {!goog.vec.vec3f.Type} vec The vector to receive the row. * @return {!goog.vec.vec3f.Type} return vec so that operations can be * chained together. */ goog.vec.mat3f.getRow = function(mat, row, vec) { vec[0] = mat[row]; vec[1] = mat[row + 3]; vec[2] = mat[row + 6]; return vec; }; /** * Sets the rows of the matrix from the supplied vectors. * * @param {!goog.vec.mat3f.Type} mat The matrix to receive the values. * @param {!goog.vec.vec3f.Type} vec0 The values for row 0. * @param {!goog.vec.vec3f.Type} vec1 The values for row 1. * @param {!goog.vec.vec3f.Type} vec2 The values for row 2. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained together. */ goog.vec.mat3f.setRows = function(mat, vec0, vec1, vec2) { goog.vec.mat3f.setRow(mat, 0, vec0); goog.vec.mat3f.setRow(mat, 1, vec1); goog.vec.mat3f.setRow(mat, 2, vec2); return /** @type {!goog.vec.mat3f.Type} */ (mat); }; /** * Retrieves the rows of the matrix into the supplied vectors. * * @param {!goog.vec.mat3f.Type} mat The matrix to supplying the values. * @param {!goog.vec.vec3f.Type} vec0 The vector to receive row 0. * @param {!goog.vec.vec3f.Type} vec1 The vector to receive row 1. * @param {!goog.vec.vec3f.Type} vec2 The vector to receive row 2. */ goog.vec.mat3f.getRows = function(mat, vec0, vec1, vec2) { goog.vec.mat3f.getRow(mat, 0, vec0); goog.vec.mat3f.getRow(mat, 1, vec1); goog.vec.mat3f.getRow(mat, 2, vec2); }; /** * Makes the given 3x3 matrix the zero matrix. * * @param {!goog.vec.mat3f.Type} mat The matrix. * @return {!goog.vec.mat3f.Type} return mat so operations can be chained. */ goog.vec.mat3f.makeZero = function(mat) { mat[0] = 0; mat[1] = 0; mat[2] = 0; mat[3] = 0; mat[4] = 0; mat[5] = 0; mat[6] = 0; mat[7] = 0; mat[8] = 0; return mat; }; /** * Makes the given 3x3 matrix the identity matrix. * * @param {!goog.vec.mat3f.Type} mat The matrix. * @return {!goog.vec.mat3f.Type} return mat so operations can be chained. */ goog.vec.mat3f.makeIdentity = function(mat) { mat[0] = 1; mat[1] = 0; mat[2] = 0; mat[3] = 0; mat[4] = 1; mat[5] = 0; mat[6] = 0; mat[7] = 0; mat[8] = 1; return mat; }; /** * Performs a per-component addition of the matrices mat0 and mat1, storing * the result into resultMat. * * @param {!goog.vec.mat3f.Type} mat0 The first addend. * @param {!goog.vec.mat3f.Type} mat1 The second addend. * @param {!goog.vec.mat3f.Type} resultMat The matrix to * receive the results (may be either mat0 or mat1). * @return {!goog.vec.mat3f.Type} return resultMat so that operations can be * chained together. */ goog.vec.mat3f.addMat = function(mat0, mat1, resultMat) { resultMat[0] = mat0[0] + mat1[0]; resultMat[1] = mat0[1] + mat1[1]; resultMat[2] = mat0[2] + mat1[2]; resultMat[3] = mat0[3] + mat1[3]; resultMat[4] = mat0[4] + mat1[4]; resultMat[5] = mat0[5] + mat1[5]; resultMat[6] = mat0[6] + mat1[6]; resultMat[7] = mat0[7] + mat1[7]; resultMat[8] = mat0[8] + mat1[8]; return resultMat; }; /** * Performs a per-component subtraction of the matrices mat0 and mat1, * storing the result into resultMat. * * @param {!goog.vec.mat3f.Type} mat0 The minuend. * @param {!goog.vec.mat3f.Type} mat1 The subtrahend. * @param {!goog.vec.mat3f.Type} resultMat The matrix to receive * the results (may be either mat0 or mat1). * @return {!goog.vec.mat3f.Type} return resultMat so that operations can be * chained together. */ goog.vec.mat3f.subMat = function(mat0, mat1, resultMat) { resultMat[0] = mat0[0] - mat1[0]; resultMat[1] = mat0[1] - mat1[1]; resultMat[2] = mat0[2] - mat1[2]; resultMat[3] = mat0[3] - mat1[3]; resultMat[4] = mat0[4] - mat1[4]; resultMat[5] = mat0[5] - mat1[5]; resultMat[6] = mat0[6] - mat1[6]; resultMat[7] = mat0[7] - mat1[7]; resultMat[8] = mat0[8] - mat1[8]; return resultMat; }; /** * Multiplies matrix mat0 with the given scalar, storing the result * into resultMat. * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {number} scalar The scalar value to multiple to each element of mat. * @param {!goog.vec.mat3f.Type} resultMat The matrix to receive * the results (may be mat). * @return {!goog.vec.mat3f.Type} return resultMat so that operations can be * chained together. */ goog.vec.mat3f.multScalar = function(mat, scalar, resultMat) { resultMat[0] = mat[0] * scalar; resultMat[1] = mat[1] * scalar; resultMat[2] = mat[2] * scalar; resultMat[3] = mat[3] * scalar; resultMat[4] = mat[4] * scalar; resultMat[5] = mat[5] * scalar; resultMat[6] = mat[6] * scalar; resultMat[7] = mat[7] * scalar; resultMat[8] = mat[8] * scalar; return resultMat; }; /** * Multiplies the two matrices mat0 and mat1 using matrix multiplication, * storing the result into resultMat. * * @param {!goog.vec.mat3f.Type} mat0 The first (left hand) matrix. * @param {!goog.vec.mat3f.Type} mat1 The second (right hand) matrix. * @param {!goog.vec.mat3f.Type} resultMat The matrix to receive * the results (may be either mat0 or mat1). * @return {!goog.vec.mat3f.Type} return resultMat so that operations can be * chained together. */ goog.vec.mat3f.multMat = function(mat0, mat1, resultMat) { var a00 = mat0[0], a10 = mat0[1], a20 = mat0[2]; var a01 = mat0[3], a11 = mat0[4], a21 = mat0[5]; var a02 = mat0[6], a12 = mat0[7], a22 = mat0[8]; var b00 = mat1[0], b10 = mat1[1], b20 = mat1[2]; var b01 = mat1[3], b11 = mat1[4], b21 = mat1[5]; var b02 = mat1[6], b12 = mat1[7], b22 = mat1[8]; resultMat[0] = a00 * b00 + a01 * b10 + a02 * b20; resultMat[1] = a10 * b00 + a11 * b10 + a12 * b20; resultMat[2] = a20 * b00 + a21 * b10 + a22 * b20; resultMat[3] = a00 * b01 + a01 * b11 + a02 * b21; resultMat[4] = a10 * b01 + a11 * b11 + a12 * b21; resultMat[5] = a20 * b01 + a21 * b11 + a22 * b21; resultMat[6] = a00 * b02 + a01 * b12 + a02 * b22; resultMat[7] = a10 * b02 + a11 * b12 + a12 * b22; resultMat[8] = a20 * b02 + a21 * b12 + a22 * b22; return resultMat; }; /** * Transposes the given matrix mat storing the result into resultMat. * * @param {!goog.vec.mat3f.Type} mat The matrix to transpose. * @param {!goog.vec.mat3f.Type} resultMat The matrix to receive * the results (may be mat). * @return {!goog.vec.mat3f.Type} return resultMat so that operations can be * chained together. */ goog.vec.mat3f.transpose = function(mat, resultMat) { if (resultMat == mat) { var a10 = mat[1], a20 = mat[2], a21 = mat[5]; resultMat[1] = mat[3]; resultMat[2] = mat[6]; resultMat[3] = a10; resultMat[5] = mat[7]; resultMat[6] = a20; resultMat[7] = a21; } else { resultMat[0] = mat[0]; resultMat[1] = mat[3]; resultMat[2] = mat[6]; resultMat[3] = mat[1]; resultMat[4] = mat[4]; resultMat[5] = mat[7]; resultMat[6] = mat[2]; resultMat[7] = mat[5]; resultMat[8] = mat[8]; } return resultMat; }; /** * Computes the inverse of mat0 storing the result into resultMat. If the * inverse is defined, this function returns true, false otherwise. * * @param {!goog.vec.mat3f.Type} mat0 The matrix to invert. * @param {!goog.vec.mat3f.Type} resultMat The matrix to receive * the result (may be mat0). * @return {boolean} True if the inverse is defined. If false is returned, * resultMat is not modified. */ goog.vec.mat3f.invert = function(mat0, resultMat) { var a00 = mat0[0], a10 = mat0[1], a20 = mat0[2]; var a01 = mat0[3], a11 = mat0[4], a21 = mat0[5]; var a02 = mat0[6], a12 = mat0[7], a22 = mat0[8]; var t00 = a11 * a22 - a12 * a21; var t10 = a12 * a20 - a10 * a22; var t20 = a10 * a21 - a11 * a20; var det = a00 * t00 + a01 * t10 + a02 * t20; if (det == 0) { return false; } var idet = 1 / det; resultMat[0] = t00 * idet; resultMat[3] = (a02 * a21 - a01 * a22) * idet; resultMat[6] = (a01 * a12 - a02 * a11) * idet; resultMat[1] = t10 * idet; resultMat[4] = (a00 * a22 - a02 * a20) * idet; resultMat[7] = (a02 * a10 - a00 * a12) * idet; resultMat[2] = t20 * idet; resultMat[5] = (a01 * a20 - a00 * a21) * idet; resultMat[8] = (a00 * a11 - a01 * a10) * idet; return true; }; /** * Returns true if the components of mat0 are equal to the components of mat1. * * @param {!goog.vec.mat3f.Type} mat0 The first matrix. * @param {!goog.vec.mat3f.Type} mat1 The second matrix. * @return {boolean} True if the the two matrices are equivalent. */ goog.vec.mat3f.equals = function(mat0, mat1) { return mat0.length == mat1.length && mat0[0] == mat1[0] && mat0[1] == mat1[1] && mat0[2] == mat1[2] && mat0[3] == mat1[3] && mat0[4] == mat1[4] && mat0[5] == mat1[5] && mat0[6] == mat1[6] && mat0[7] == mat1[7] && mat0[8] == mat1[8]; }; /** * Transforms the given vector with the given matrix storing the resulting, * transformed matrix into resultVec. * * @param {!goog.vec.mat3f.Type} mat The matrix supplying the transformation. * @param {!goog.vec.vec3f.Type} vec The vector to transform. * @param {!goog.vec.vec3f.Type} resultVec The vector to * receive the results (may be vec). * @return {!goog.vec.vec3f.Type} return resultVec so that operations can be * chained together. */ goog.vec.mat3f.multVec3 = function(mat, vec, resultVec) { var x = vec[0], y = vec[1], z = vec[2]; resultVec[0] = x * mat[0] + y * mat[3] + z * mat[6]; resultVec[1] = x * mat[1] + y * mat[4] + z * mat[7]; resultVec[2] = x * mat[2] + y * mat[5] + z * mat[8]; return resultVec; }; /** * Makes the given 3x3 matrix a translation matrix with x and y * translation values. * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {number} x The translation along the x axis. * @param {number} y The translation along the y axis. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained. */ goog.vec.mat3f.makeTranslate = function(mat, x, y) { mat[0] = 1; mat[1] = 0; mat[2] = 0; mat[3] = 0; mat[4] = 1; mat[5] = 0; mat[6] = x; mat[7] = y; mat[8] = 1; return mat; }; /** * Makes the given 3x3 matrix a scale matrix with x, y, and z scale factors. * * @param {!goog.vec.mat3f.Type} mat The 3x3 (9-element) matrix * array to receive the new scale matrix. * @param {number} x The scale along the x axis. * @param {number} y The scale along the y axis. * @param {number} z The scale along the z axis. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained. */ goog.vec.mat3f.makeScale = function(mat, x, y, z) { mat[0] = x; mat[1] = 0; mat[2] = 0; mat[3] = 0; mat[4] = y; mat[5] = 0; mat[6] = 0; mat[7] = 0; mat[8] = z; return mat; }; /** * Makes the given 3x3 matrix a rotation matrix with the given rotation * angle about the axis defined by the vector (ax, ay, az). * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {number} angle The rotation angle in radians. * @param {number} ax The x component of the rotation axis. * @param {number} ay The y component of the rotation axis. * @param {number} az The z component of the rotation axis. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained. */ goog.vec.mat3f.makeRotate = function(mat, angle, ax, ay, az) { var c = Math.cos(angle); var d = 1 - c; var s = Math.sin(angle); mat[0] = ax * ax * d + c; mat[1] = ax * ay * d + az * s; mat[2] = ax * az * d - ay * s; mat[3] = ax * ay * d - az * s; mat[4] = ay * ay * d + c; mat[5] = ay * az * d + ax * s; mat[6] = ax * az * d + ay * s; mat[7] = ay * az * d - ax * s; mat[8] = az * az * d + c; return mat; }; /** * Makes the given 3x3 matrix a rotation matrix with the given rotation * angle about the X axis. * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {number} angle The rotation angle in radians. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained. */ goog.vec.mat3f.makeRotateX = function(mat, angle) { var c = Math.cos(angle); var s = Math.sin(angle); mat[0] = 1; mat[1] = 0; mat[2] = 0; mat[3] = 0; mat[4] = c; mat[5] = s; mat[6] = 0; mat[7] = -s; mat[8] = c; return mat; }; /** * Makes the given 3x3 matrix a rotation matrix with the given rotation * angle about the Y axis. * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {number} angle The rotation angle in radians. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained. */ goog.vec.mat3f.makeRotateY = function(mat, angle) { var c = Math.cos(angle); var s = Math.sin(angle); mat[0] = c; mat[1] = 0; mat[2] = -s; mat[3] = 0; mat[4] = 1; mat[5] = 0; mat[6] = s; mat[7] = 0; mat[8] = c; return mat; }; /** * Makes the given 3x3 matrix a rotation matrix with the given rotation * angle about the Z axis. * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {number} angle The rotation angle in radians. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained. */ goog.vec.mat3f.makeRotateZ = function(mat, angle) { var c = Math.cos(angle); var s = Math.sin(angle); mat[0] = c; mat[1] = s; mat[2] = 0; mat[3] = -s; mat[4] = c; mat[5] = 0; mat[6] = 0; mat[7] = 0; mat[8] = 1; return mat; }; /** * Rotate the given matrix by angle about the x,y,z axis. Equivalent to: * goog.vec.mat3f.multMat( * mat, * goog.vec.mat3f.makeRotate(goog.vec.mat3f.create(), angle, x, y, z), * mat); * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {number} angle The angle in radians. * @param {number} x The x component of the rotation axis. * @param {number} y The y component of the rotation axis. * @param {number} z The z component of the rotation axis. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained. */ goog.vec.mat3f.rotate = function(mat, angle, x, y, z) { var m00 = mat[0], m10 = mat[1], m20 = mat[2]; var m01 = mat[3], m11 = mat[4], m21 = mat[5]; var m02 = mat[6], m12 = mat[7], m22 = mat[8]; var cosAngle = Math.cos(angle); var sinAngle = Math.sin(angle); var diffCosAngle = 1 - cosAngle; var r00 = x * x * diffCosAngle + cosAngle; var r10 = x * y * diffCosAngle + z * sinAngle; var r20 = x * z * diffCosAngle - y * sinAngle; var r01 = x * y * diffCosAngle - z * sinAngle; var r11 = y * y * diffCosAngle + cosAngle; var r21 = y * z * diffCosAngle + x * sinAngle; var r02 = x * z * diffCosAngle + y * sinAngle; var r12 = y * z * diffCosAngle - x * sinAngle; var r22 = z * z * diffCosAngle + cosAngle; mat[0] = m00 * r00 + m01 * r10 + m02 * r20; mat[1] = m10 * r00 + m11 * r10 + m12 * r20; mat[2] = m20 * r00 + m21 * r10 + m22 * r20; mat[3] = m00 * r01 + m01 * r11 + m02 * r21; mat[4] = m10 * r01 + m11 * r11 + m12 * r21; mat[5] = m20 * r01 + m21 * r11 + m22 * r21; mat[6] = m00 * r02 + m01 * r12 + m02 * r22; mat[7] = m10 * r02 + m11 * r12 + m12 * r22; mat[8] = m20 * r02 + m21 * r12 + m22 * r22; return mat; }; /** * Rotate the given matrix by angle about the x axis. Equivalent to: * goog.vec.mat3f.multMat( * mat, * goog.vec.mat3f.makeRotateX(goog.vec.mat3f.create(), angle), * mat); * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {number} angle The angle in radians. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained. */ goog.vec.mat3f.rotateX = function(mat, angle) { var m01 = mat[3], m11 = mat[4], m21 = mat[5]; var m02 = mat[6], m12 = mat[7], m22 = mat[8]; var c = Math.cos(angle); var s = Math.sin(angle); mat[3] = m01 * c + m02 * s; mat[4] = m11 * c + m12 * s; mat[5] = m21 * c + m22 * s; mat[6] = m01 * -s + m02 * c; mat[7] = m11 * -s + m12 * c; mat[8] = m21 * -s + m22 * c; return mat; }; /** * Rotate the given matrix by angle about the y axis. Equivalent to: * goog.vec.mat3f.multMat( * mat, * goog.vec.mat3f.makeRotateY(goog.vec.mat3f.create(), angle), * mat); * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {number} angle The angle in radians. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained. */ goog.vec.mat3f.rotateY = function(mat, angle) { var m00 = mat[0], m10 = mat[1], m20 = mat[2]; var m02 = mat[6], m12 = mat[7], m22 = mat[8]; var c = Math.cos(angle); var s = Math.sin(angle); mat[0] = m00 * c + m02 * -s; mat[1] = m10 * c + m12 * -s; mat[2] = m20 * c + m22 * -s; mat[6] = m00 * s + m02 * c; mat[7] = m10 * s + m12 * c; mat[8] = m20 * s + m22 * c; return mat; }; /** * Rotate the given matrix by angle about the z axis. Equivalent to: * goog.vec.mat3f.multMat( * mat, * goog.vec.mat3f.makeRotateZ(goog.vec.mat3f.create(), angle), * mat); * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {number} angle The angle in radians. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained. */ goog.vec.mat3f.rotateZ = function(mat, angle) { var m00 = mat[0], m10 = mat[1], m20 = mat[2]; var m01 = mat[3], m11 = mat[4], m21 = mat[5]; var c = Math.cos(angle); var s = Math.sin(angle); mat[0] = m00 * c + m01 * s; mat[1] = m10 * c + m11 * s; mat[2] = m20 * c + m21 * s; mat[3] = m00 * -s + m01 * c; mat[4] = m10 * -s + m11 * c; mat[5] = m20 * -s + m21 * c; return mat; }; /** * Makes the given 3x3 matrix a rotation matrix given Euler angles using * the ZXZ convention. * Given the euler angles [theta1, theta2, theta3], the rotation is defined as * rotation = rotation_z(theta1) * rotation_x(theta2) * rotation_z(theta3), * with theta1 in [0, 2 * pi], theta2 in [0, pi] and theta3 in [0, 2 * pi]. * rotation_x(theta) means rotation around the X axis of theta radians. * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {number} theta1 The angle of rotation around the Z axis in radians. * @param {number} theta2 The angle of rotation around the X axis in radians. * @param {number} theta3 The angle of rotation around the Z axis in radians. * @return {!goog.vec.mat3f.Type} return mat so that operations can be * chained. */ goog.vec.mat3f.makeEulerZXZ = function(mat, theta1, theta2, theta3) { var c1 = Math.cos(theta1); var s1 = Math.sin(theta1); var c2 = Math.cos(theta2); var s2 = Math.sin(theta2); var c3 = Math.cos(theta3); var s3 = Math.sin(theta3); mat[0] = c1 * c3 - c2 * s1 * s3; mat[1] = c2 * c1 * s3 + c3 * s1; mat[2] = s3 * s2; mat[3] = -c1 * s3 - c3 * c2 * s1; mat[4] = c1 * c2 * c3 - s1 * s3; mat[5] = c3 * s2; mat[6] = s2 * s1; mat[7] = -c1 * s2; mat[8] = c2; return mat; }; /** * Decomposes a rotation matrix into Euler angles using the ZXZ convention so * that rotation = rotation_z(theta1) * rotation_x(theta2) * rotation_z(theta3), * with theta1 in [0, 2 * pi], theta2 in [0, pi] and theta3 in [0, 2 * pi]. * rotation_x(theta) means rotation around the X axis of theta radians. * * @param {!goog.vec.mat3f.Type} mat The matrix. * @param {!goog.vec.vec3f.Type} euler The ZXZ Euler angles in * radians as [theta1, theta2, theta3]. * @param {boolean=} opt_theta2IsNegative Whether theta2 is in [-pi, 0] instead * of the default [0, pi]. * @return {!goog.vec.vec3f.Type} return euler so that operations can be * chained together. */ goog.vec.mat3f.toEulerZXZ = function(mat, euler, opt_theta2IsNegative) { // There is an ambiguity in the sign of sinTheta2 because of the sqrt. var sinTheta2 = Math.sqrt(mat[2] * mat[2] + mat[5] * mat[5]); // By default we explicitely constrain theta2 to be in [0, pi], // so sinTheta2 is always positive. We can change the behavior and specify // theta2 to be negative in [-pi, 0] with opt_Theta2IsNegative. var signTheta2 = opt_theta2IsNegative ? -1 : 1; if (sinTheta2 > goog.vec.EPSILON) { euler[2] = Math.atan2(mat[2] * signTheta2, mat[5] * signTheta2); euler[1] = Math.atan2(sinTheta2 * signTheta2, mat[8]); euler[0] = Math.atan2(mat[6] * signTheta2, -mat[7] * signTheta2); } else { // There is also an arbitrary choice for theta1 = 0 or theta2 = 0 here. // We assume theta1 = 0 as some applications do not allow the camera to roll // (i.e. have theta1 != 0). euler[0] = 0; euler[1] = Math.atan2(sinTheta2 * signTheta2, mat[8]); euler[2] = Math.atan2(mat[1], mat[0]); } // Atan2 outputs angles in [-pi, pi] so we bring them back to [0, 2 * pi]. euler[0] = (euler[0] + Math.PI * 2) % (Math.PI * 2); euler[2] = (euler[2] + Math.PI * 2) % (Math.PI * 2); // For theta2 we want the angle to be in [0, pi] or [-pi, 0] depending on // signTheta2. euler[1] = ((euler[1] * signTheta2 + Math.PI * 2) % (Math.PI * 2)) * signTheta2; return euler; };