simple-squiggle/node_modules/mathjs/lib/cjs/function/algebra/solver/usolve.js

"use strict";

Object.defineProperty(exports, "__esModule", {
  value: true
});
exports.createUsolve = void 0;

var _factory = require("../../../utils/factory.js");

var _solveValidation = require("./utils/solveValidation.js");

var name = 'usolve';
var dependencies = ['typed', 'matrix', 'divideScalar', 'multiplyScalar', 'subtract', 'equalScalar', 'DenseMatrix'];
var createUsolve = /* #__PURE__ */(0, _factory.factory)(name, dependencies, function (_ref) {
  var typed = _ref.typed,
      matrix = _ref.matrix,
      divideScalar = _ref.divideScalar,
      multiplyScalar = _ref.multiplyScalar,
      subtract = _ref.subtract,
      equalScalar = _ref.equalScalar,
      DenseMatrix = _ref.DenseMatrix;
  var solveValidation = (0, _solveValidation.createSolveValidation)({
    DenseMatrix: DenseMatrix
  });
  /**
   * Finds one solution of a linear equation system by backward substitution. Matrix must be an upper triangular matrix. Throws an error if there's no solution.
   *
   * `U * x = b`
   *
   * Syntax:
   *
   *    math.usolve(U, b)
   *
   * Examples:
   *
   *    const a = [[-2, 3], [2, 1]]
   *    const b = [11, 9]
   *    const x = usolve(a, b)  // [[8], [9]]
   *
   * See also:
   *
   *    usolveAll, lup, slu, usolve, lusolve
   *
   * @param {Matrix, Array} U       A N x N matrix or array (U)
   * @param {Matrix, Array} b       A column vector with the b values
   *
   * @return {DenseMatrix | Array}  A column vector with the linear system solution (x)
   */

  return typed(name, {
    'SparseMatrix, Array | Matrix': function SparseMatrixArrayMatrix(m, b) {
      return _sparseBackwardSubstitution(m, b);
    },
    'DenseMatrix, Array | Matrix': function DenseMatrixArrayMatrix(m, b) {
      return _denseBackwardSubstitution(m, b);
    },
    'Array, Array | Matrix': function ArrayArrayMatrix(a, b) {
      var m = matrix(a);

      var r = _denseBackwardSubstitution(m, b);

      return r.valueOf();
    }
  });

  function _denseBackwardSubstitution(m, b) {
    // make b into a column vector
    b = solveValidation(m, b, true);
    var bdata = b._data;
    var rows = m._size[0];
    var columns = m._size[1]; // result

    var x = [];
    var mdata = m._data; // loop columns backwards

    for (var j = columns - 1; j >= 0; j--) {
      // b[j]
      var bj = bdata[j][0] || 0; // x[j]

      var xj = void 0;

      if (!equalScalar(bj, 0)) {
        // value at [j, j]
        var vjj = mdata[j][j];

        if (equalScalar(vjj, 0)) {
          // system cannot be solved
          throw new Error('Linear system cannot be solved since matrix is singular');
        }

        xj = divideScalar(bj, vjj); // loop rows

        for (var i = j - 1; i >= 0; i--) {
          // update copy of b
          bdata[i] = [subtract(bdata[i][0] || 0, multiplyScalar(xj, mdata[i][j]))];
        }
      } else {
        // zero value at j
        xj = 0;
      } // update x


      x[j] = [xj];
    }

    return new DenseMatrix({
      data: x,
      size: [rows, 1]
    });
  }

  function _sparseBackwardSubstitution(m, b) {
    // make b into a column vector
    b = solveValidation(m, b, true);
    var bdata = b._data;
    var rows = m._size[0];
    var columns = m._size[1];
    var values = m._values;
    var index = m._index;
    var ptr = m._ptr; // result

    var x = []; // loop columns backwards

    for (var j = columns - 1; j >= 0; j--) {
      var bj = bdata[j][0] || 0;

      if (!equalScalar(bj, 0)) {
        // non-degenerate row, find solution
        var vjj = 0; // upper triangular matrix values & index (column j)

        var jValues = [];
        var jIndices = []; // first & last indeces in column

        var firstIndex = ptr[j];
        var lastIndex = ptr[j + 1]; // values in column, find value at [j, j], loop backwards

        for (var k = lastIndex - 1; k >= firstIndex; k--) {
          var i = index[k]; // check row (rows are not sorted!)

          if (i === j) {
            vjj = values[k];
          } else if (i < j) {
            // store upper triangular
            jValues.push(values[k]);
            jIndices.push(i);
          }
        } // at this point we must have a value in vjj


        if (equalScalar(vjj, 0)) {
          throw new Error('Linear system cannot be solved since matrix is singular');
        }

        var xj = divideScalar(bj, vjj);

        for (var _k = 0, _lastIndex = jIndices.length; _k < _lastIndex; _k++) {
          var _i = jIndices[_k];
          bdata[_i] = [subtract(bdata[_i][0], multiplyScalar(xj, jValues[_k]))];
        }

        x[j] = [xj];
      } else {
        // degenerate row, we can choose any value
        x[j] = [0];
      }
    }

    return new DenseMatrix({
      data: x,
      size: [rows, 1]
    });
  }
});
exports.createUsolve = createUsolve;
feat: Proof of concept of simple squiggle 2022-04-15 01:48:30 +00:00			`"use strict";`

			`Object.defineProperty(exports, "__esModule", {`
			`value: true`
			`});`
			`exports.createUsolve = void 0;`

			`var _factory = require("../../../utils/factory.js");`

			`var _solveValidation = require("./utils/solveValidation.js");`

			`var name = 'usolve';`
			`var dependencies = ['typed', 'matrix', 'divideScalar', 'multiplyScalar', 'subtract', 'equalScalar', 'DenseMatrix'];`
			`var createUsolve = /* #__PURE__ */(0, _factory.factory)(name, dependencies, function (_ref) {`
			`var typed = _ref.typed,`
			`matrix = _ref.matrix,`
			`divideScalar = _ref.divideScalar,`
			`multiplyScalar = _ref.multiplyScalar,`
			`subtract = _ref.subtract,`
			`equalScalar = _ref.equalScalar,`
			`DenseMatrix = _ref.DenseMatrix;`
			`var solveValidation = (0, _solveValidation.createSolveValidation)({`
			`DenseMatrix: DenseMatrix`
			`});`
			`/**`
			`* Finds one solution of a linear equation system by backward substitution. Matrix must be an upper triangular matrix. Throws an error if there's no solution.`
			`*`
			* `U * x = b`
			`*`
			`* Syntax:`
			`*`
			`* math.usolve(U, b)`
			`*`
			`* Examples:`
			`*`
			`* const a = [[-2, 3], [2, 1]]`
			`* const b = [11, 9]`
			`* const x = usolve(a, b) // [[8], [9]]`
			`*`
			`* See also:`
			`*`
			`* usolveAll, lup, slu, usolve, lusolve`
			`*`
			`* @param {Matrix, Array} U A N x N matrix or array (U)`
			`* @param {Matrix, Array} b A column vector with the b values`
			`*`
			`* @return {DenseMatrix \| Array} A column vector with the linear system solution (x)`
			`*/`

			`return typed(name, {`
			`'SparseMatrix, Array \| Matrix': function SparseMatrixArrayMatrix(m, b) {`
			`return _sparseBackwardSubstitution(m, b);`
			`},`
			`'DenseMatrix, Array \| Matrix': function DenseMatrixArrayMatrix(m, b) {`
			`return _denseBackwardSubstitution(m, b);`
			`},`
			`'Array, Array \| Matrix': function ArrayArrayMatrix(a, b) {`
			`var m = matrix(a);`

			`var r = _denseBackwardSubstitution(m, b);`

			`return r.valueOf();`
			`}`
			`});`

			`function _denseBackwardSubstitution(m, b) {`
			`// make b into a column vector`
			`b = solveValidation(m, b, true);`
			`var bdata = b._data;`
			`var rows = m._size[0];`
			`var columns = m._size[1]; // result`

			`var x = [];`
			`var mdata = m._data; // loop columns backwards`

			`for (var j = columns - 1; j >= 0; j--) {`
			`// b[j]`
			`var bj = bdata[j][0] \|\| 0; // x[j]`

			`var xj = void 0;`

			`if (!equalScalar(bj, 0)) {`
			`// value at [j, j]`
			`var vjj = mdata[j][j];`

			`if (equalScalar(vjj, 0)) {`
			`// system cannot be solved`
			`throw new Error('Linear system cannot be solved since matrix is singular');`
			`}`

			`xj = divideScalar(bj, vjj); // loop rows`

			`for (var i = j - 1; i >= 0; i--) {`
			`// update copy of b`
			`bdata[i] = [subtract(bdata[i][0] \|\| 0, multiplyScalar(xj, mdata[i][j]))];`
			`}`
			`} else {`
			`// zero value at j`
			`xj = 0;`
			`} // update x`


			`x[j] = [xj];`
			`}`

			`return new DenseMatrix({`
			`data: x,`
			`size: [rows, 1]`
			`});`
			`}`

			`function _sparseBackwardSubstitution(m, b) {`
			`// make b into a column vector`
			`b = solveValidation(m, b, true);`
			`var bdata = b._data;`
			`var rows = m._size[0];`
			`var columns = m._size[1];`
			`var values = m._values;`
			`var index = m._index;`
			`var ptr = m._ptr; // result`

			`var x = []; // loop columns backwards`

			`for (var j = columns - 1; j >= 0; j--) {`
			`var bj = bdata[j][0] \|\| 0;`

			`if (!equalScalar(bj, 0)) {`
			`// non-degenerate row, find solution`
			`var vjj = 0; // upper triangular matrix values & index (column j)`

			`var jValues = [];`
			`var jIndices = []; // first & last indeces in column`

			`var firstIndex = ptr[j];`
			`var lastIndex = ptr[j + 1]; // values in column, find value at [j, j], loop backwards`

			`for (var k = lastIndex - 1; k >= firstIndex; k--) {`
			`var i = index[k]; // check row (rows are not sorted!)`

			`if (i === j) {`
			`vjj = values[k];`
			`} else if (i < j) {`
			`// store upper triangular`
			`jValues.push(values[k]);`
			`jIndices.push(i);`
			`}`
			`} // at this point we must have a value in vjj`


			`if (equalScalar(vjj, 0)) {`
			`throw new Error('Linear system cannot be solved since matrix is singular');`
			`}`

			`var xj = divideScalar(bj, vjj);`

			`for (var _k = 0, _lastIndex = jIndices.length; _k < _lastIndex; _k++) {`
			`var _i = jIndices[_k];`
			`bdata[_i] = [subtract(bdata[_i][0], multiplyScalar(xj, jValues[_k]))];`
			`}`

			`x[j] = [xj];`
			`} else {`
			`// degenerate row, we can choose any value`
			`x[j] = [0];`
			`}`
			`}`

			`return new DenseMatrix({`
			`data: x,`
			`size: [rows, 1]`
			`});`
			`}`
			`});`
			`exports.createUsolve = createUsolve;`