jiangchengfeiyi-xiaochengxu/node_modules/mathjs/lib/cjs/function/arithmetic/multiply.js

"use strict";

Object.defineProperty(exports, "__esModule", {
  value: true
});
exports.createMultiply = void 0;
var _factory = require("../../utils/factory.js");
var _is = require("../../utils/is.js");
var _array = require("../../utils/array.js");
var _matAlgo11xS0s = require("../../type/matrix/utils/matAlgo11xS0s.js");
var _matAlgo14xDs = require("../../type/matrix/utils/matAlgo14xDs.js");
const name = 'multiply';
const dependencies = ['typed', 'matrix', 'addScalar', 'multiplyScalar', 'equalScalar', 'dot'];
const createMultiply = exports.createMultiply = /* #__PURE__ */(0, _factory.factory)(name, dependencies, _ref => {
  let {
    typed,
    matrix,
    addScalar,
    multiplyScalar,
    equalScalar,
    dot
  } = _ref;
  const matAlgo11xS0s = (0, _matAlgo11xS0s.createMatAlgo11xS0s)({
    typed,
    equalScalar
  });
  const matAlgo14xDs = (0, _matAlgo14xDs.createMatAlgo14xDs)({
    typed
  });
  function _validateMatrixDimensions(size1, size2) {
    // check left operand dimensions
    switch (size1.length) {
      case 1:
        // check size2
        switch (size2.length) {
          case 1:
            // Vector x Vector
            if (size1[0] !== size2[0]) {
              // throw error
              throw new RangeError('Dimension mismatch in multiplication. Vectors must have the same length');
            }
            break;
          case 2:
            // Vector x Matrix
            if (size1[0] !== size2[0]) {
              // throw error
              throw new RangeError('Dimension mismatch in multiplication. Vector length (' + size1[0] + ') must match Matrix rows (' + size2[0] + ')');
            }
            break;
          default:
            throw new Error('Can only multiply a 1 or 2 dimensional matrix (Matrix B has ' + size2.length + ' dimensions)');
        }
        break;
      case 2:
        // check size2
        switch (size2.length) {
          case 1:
            // Matrix x Vector
            if (size1[1] !== size2[0]) {
              // throw error
              throw new RangeError('Dimension mismatch in multiplication. Matrix columns (' + size1[1] + ') must match Vector length (' + size2[0] + ')');
            }
            break;
          case 2:
            // Matrix x Matrix
            if (size1[1] !== size2[0]) {
              // throw error
              throw new RangeError('Dimension mismatch in multiplication. Matrix A columns (' + size1[1] + ') must match Matrix B rows (' + size2[0] + ')');
            }
            break;
          default:
            throw new Error('Can only multiply a 1 or 2 dimensional matrix (Matrix B has ' + size2.length + ' dimensions)');
        }
        break;
      default:
        throw new Error('Can only multiply a 1 or 2 dimensional matrix (Matrix A has ' + size1.length + ' dimensions)');
    }
  }

  /**
   * C = A * B
   *
   * @param {Matrix} a            Dense Vector   (N)
   * @param {Matrix} b            Dense Vector   (N)
   *
   * @return {number}             Scalar value
   */
  function _multiplyVectorVector(a, b, n) {
    // check empty vector
    if (n === 0) {
      throw new Error('Cannot multiply two empty vectors');
    }
    return dot(a, b);
  }

  /**
   * C = A * B
   *
   * @param {Matrix} a            Dense Vector   (M)
   * @param {Matrix} b            Matrix         (MxN)
   *
   * @return {Matrix}             Dense Vector   (N)
   */
  function _multiplyVectorMatrix(a, b) {
    // process storage
    if (b.storage() !== 'dense') {
      throw new Error('Support for SparseMatrix not implemented');
    }
    return _multiplyVectorDenseMatrix(a, b);
  }

  /**
   * C = A * B
   *
   * @param {Matrix} a            Dense Vector   (M)
   * @param {Matrix} b            Dense Matrix   (MxN)
   *
   * @return {Matrix}             Dense Vector   (N)
   */
  function _multiplyVectorDenseMatrix(a, b) {
    // a dense
    const adata = a._data;
    const asize = a._size;
    const adt = a._datatype || a.getDataType();
    // b dense
    const bdata = b._data;
    const bsize = b._size;
    const bdt = b._datatype || b.getDataType();
    // rows & columns
    const alength = asize[0];
    const bcolumns = bsize[1];

    // datatype
    let dt;
    // addScalar signature to use
    let af = addScalar;
    // multiplyScalar signature to use
    let mf = multiplyScalar;

    // process data types
    if (adt && bdt && adt === bdt && typeof adt === 'string' && adt !== 'mixed') {
      // datatype
      dt = adt;
      // find signatures that matches (dt, dt)
      af = typed.find(addScalar, [dt, dt]);
      mf = typed.find(multiplyScalar, [dt, dt]);
    }

    // result
    const c = [];

    // loop matrix columns
    for (let j = 0; j < bcolumns; j++) {
      // sum (do not initialize it with zero)
      let sum = mf(adata[0], bdata[0][j]);
      // loop vector
      for (let i = 1; i < alength; i++) {
        // multiply & accumulate
        sum = af(sum, mf(adata[i], bdata[i][j]));
      }
      c[j] = sum;
    }

    // return matrix
    return a.createDenseMatrix({
      data: c,
      size: [bcolumns],
      datatype: adt === a._datatype && bdt === b._datatype ? dt : undefined
    });
  }

  /**
   * C = A * B
   *
   * @param {Matrix} a            Matrix         (MxN)
   * @param {Matrix} b            Dense Vector   (N)
   *
   * @return {Matrix}             Dense Vector   (M)
   */
  const _multiplyMatrixVector = typed('_multiplyMatrixVector', {
    'DenseMatrix, any': _multiplyDenseMatrixVector,
    'SparseMatrix, any': _multiplySparseMatrixVector
  });

  /**
   * C = A * B
   *
   * @param {Matrix} a            Matrix         (MxN)
   * @param {Matrix} b            Matrix         (NxC)
   *
   * @return {Matrix}             Matrix         (MxC)
   */
  const _multiplyMatrixMatrix = typed('_multiplyMatrixMatrix', {
    'DenseMatrix, DenseMatrix': _multiplyDenseMatrixDenseMatrix,
    'DenseMatrix, SparseMatrix': _multiplyDenseMatrixSparseMatrix,
    'SparseMatrix, DenseMatrix': _multiplySparseMatrixDenseMatrix,
    'SparseMatrix, SparseMatrix': _multiplySparseMatrixSparseMatrix
  });

  /**
   * C = A * B
   *
   * @param {Matrix} a            DenseMatrix  (MxN)
   * @param {Matrix} b            Dense Vector (N)
   *
   * @return {Matrix}             Dense Vector (M)
   */
  function _multiplyDenseMatrixVector(a, b) {
    // a dense
    const adata = a._data;
    const asize = a._size;
    const adt = a._datatype || a.getDataType();
    // b dense
    const bdata = b._data;
    const bdt = b._datatype || b.getDataType();
    // rows & columns
    const arows = asize[0];
    const acolumns = asize[1];

    // datatype
    let dt;
    // addScalar signature to use
    let af = addScalar;
    // multiplyScalar signature to use
    let mf = multiplyScalar;

    // process data types
    if (adt && bdt && adt === bdt && typeof adt === 'string' && adt !== 'mixed') {
      // datatype
      dt = adt;
      // find signatures that matches (dt, dt)
      af = typed.find(addScalar, [dt, dt]);
      mf = typed.find(multiplyScalar, [dt, dt]);
    }

    // result
    const c = [];

    // loop matrix a rows
    for (let i = 0; i < arows; i++) {
      // current row
      const row = adata[i];
      // sum (do not initialize it with zero)
      let sum = mf(row[0], bdata[0]);
      // loop matrix a columns
      for (let j = 1; j < acolumns; j++) {
        // multiply & accumulate
        sum = af(sum, mf(row[j], bdata[j]));
      }
      c[i] = sum;
    }

    // return matrix
    return a.createDenseMatrix({
      data: c,
      size: [arows],
      datatype: adt === a._datatype && bdt === b._datatype ? dt : undefined
    });
  }

  /**
   * C = A * B
   *
   * @param {Matrix} a            DenseMatrix    (MxN)
   * @param {Matrix} b            DenseMatrix    (NxC)
   *
   * @return {Matrix}             DenseMatrix    (MxC)
   */
  function _multiplyDenseMatrixDenseMatrix(a, b) {
    // getDataType()
    // a dense
    const adata = a._data;
    const asize = a._size;
    const adt = a._datatype || a.getDataType();
    // b dense
    const bdata = b._data;
    const bsize = b._size;
    const bdt = b._datatype || b.getDataType();
    // rows & columns
    const arows = asize[0];
    const acolumns = asize[1];
    const bcolumns = bsize[1];

    // datatype
    let dt;
    // addScalar signature to use
    let af = addScalar;
    // multiplyScalar signature to use
    let mf = multiplyScalar;

    // process data types
    if (adt && bdt && adt === bdt && typeof adt === 'string' && adt !== 'mixed' && adt !== 'mixed') {
      // datatype
      dt = adt;
      // find signatures that matches (dt, dt)
      af = typed.find(addScalar, [dt, dt]);
      mf = typed.find(multiplyScalar, [dt, dt]);
    }

    // result
    const c = [];

    // loop matrix a rows
    for (let i = 0; i < arows; i++) {
      // current row
      const row = adata[i];
      // initialize row array
      c[i] = [];
      // loop matrix b columns
      for (let j = 0; j < bcolumns; j++) {
        // sum (avoid initializing sum to zero)
        let sum = mf(row[0], bdata[0][j]);
        // loop matrix a columns
        for (let x = 1; x < acolumns; x++) {
          // multiply & accumulate
          sum = af(sum, mf(row[x], bdata[x][j]));
        }
        c[i][j] = sum;
      }
    }

    // return matrix
    return a.createDenseMatrix({
      data: c,
      size: [arows, bcolumns],
      datatype: adt === a._datatype && bdt === b._datatype ? dt : undefined
    });
  }

  /**
   * C = A * B
   *
   * @param {Matrix} a            DenseMatrix    (MxN)
   * @param {Matrix} b            SparseMatrix   (NxC)
   *
   * @return {Matrix}             SparseMatrix   (MxC)
   */
  function _multiplyDenseMatrixSparseMatrix(a, b) {
    // a dense
    const adata = a._data;
    const asize = a._size;
    const adt = a._datatype || a.getDataType();
    // b sparse
    const bvalues = b._values;
    const bindex = b._index;
    const bptr = b._ptr;
    const bsize = b._size;
    const bdt = b._datatype || b._data === undefined ? b._datatype : b.getDataType();
    // validate b matrix
    if (!bvalues) {
      throw new Error('Cannot multiply Dense Matrix times Pattern only Matrix');
    }
    // rows & columns
    const arows = asize[0];
    const bcolumns = bsize[1];

    // datatype
    let dt;
    // addScalar signature to use
    let af = addScalar;
    // multiplyScalar signature to use
    let mf = multiplyScalar;
    // equalScalar signature to use
    let eq = equalScalar;
    // zero value
    let zero = 0;

    // process data types
    if (adt && bdt && adt === bdt && typeof adt === 'string' && adt !== 'mixed') {
      // datatype
      dt = adt;
      // find signatures that matches (dt, dt)
      af = typed.find(addScalar, [dt, dt]);
      mf = typed.find(multiplyScalar, [dt, dt]);
      eq = typed.find(equalScalar, [dt, dt]);
      // convert 0 to the same datatype
      zero = typed.convert(0, dt);
    }

    // result
    const cvalues = [];
    const cindex = [];
    const cptr = [];
    // c matrix
    const c = b.createSparseMatrix({
      values: cvalues,
      index: cindex,
      ptr: cptr,
      size: [arows, bcolumns],
      datatype: adt === a._datatype && bdt === b._datatype ? dt : undefined
    });

    // loop b columns
    for (let jb = 0; jb < bcolumns; jb++) {
      // update ptr
      cptr[jb] = cindex.length;
      // indeces in column jb
      const kb0 = bptr[jb];
      const kb1 = bptr[jb + 1];
      // do not process column jb if no data exists
      if (kb1 > kb0) {
        // last row mark processed
        let last = 0;
        // loop a rows
        for (let i = 0; i < arows; i++) {
          // column mark
          const mark = i + 1;
          // C[i, jb]
          let cij;
          // values in b column j
          for (let kb = kb0; kb < kb1; kb++) {
            // row
            const ib = bindex[kb];
            // check value has been initialized
            if (last !== mark) {
              // first value in column jb
              cij = mf(adata[i][ib], bvalues[kb]);
              // update mark
              last = mark;
            } else {
              // accumulate value
              cij = af(cij, mf(adata[i][ib], bvalues[kb]));
            }
          }
          // check column has been processed and value != 0
          if (last === mark && !eq(cij, zero)) {
            // push row & value
            cindex.push(i);
            cvalues.push(cij);
          }
        }
      }
    }
    // update ptr
    cptr[bcolumns] = cindex.length;

    // return sparse matrix
    return c;
  }

  /**
   * C = A * B
   *
   * @param {Matrix} a            SparseMatrix    (MxN)
   * @param {Matrix} b            Dense Vector (N)
   *
   * @return {Matrix}             SparseMatrix    (M, 1)
   */
  function _multiplySparseMatrixVector(a, b) {
    // a sparse
    const avalues = a._values;
    const aindex = a._index;
    const aptr = a._ptr;
    const adt = a._datatype || a._data === undefined ? a._datatype : a.getDataType();
    // validate a matrix
    if (!avalues) {
      throw new Error('Cannot multiply Pattern only Matrix times Dense Matrix');
    }
    // b dense
    const bdata = b._data;
    const bdt = b._datatype || b.getDataType();
    // rows & columns
    const arows = a._size[0];
    const brows = b._size[0];
    // result
    const cvalues = [];
    const cindex = [];
    const cptr = [];

    // datatype
    let dt;
    // addScalar signature to use
    let af = addScalar;
    // multiplyScalar signature to use
    let mf = multiplyScalar;
    // equalScalar signature to use
    let eq = equalScalar;
    // zero value
    let zero = 0;

    // process data types
    if (adt && bdt && adt === bdt && typeof adt === 'string' && adt !== 'mixed') {
      // datatype
      dt = adt;
      // find signatures that matches (dt, dt)
      af = typed.find(addScalar, [dt, dt]);
      mf = typed.find(multiplyScalar, [dt, dt]);
      eq = typed.find(equalScalar, [dt, dt]);
      // convert 0 to the same datatype
      zero = typed.convert(0, dt);
    }

    // workspace
    const x = [];
    // vector with marks indicating a value x[i] exists in a given column
    const w = [];

    // update ptr
    cptr[0] = 0;
    // rows in b
    for (let ib = 0; ib < brows; ib++) {
      // b[ib]
      const vbi = bdata[ib];
      // check b[ib] != 0, avoid loops
      if (!eq(vbi, zero)) {
        // A values & index in ib column
        for (let ka0 = aptr[ib], ka1 = aptr[ib + 1], ka = ka0; ka < ka1; ka++) {
          // a row
          const ia = aindex[ka];
          // check value exists in current j
          if (!w[ia]) {
            // ia is new entry in j
            w[ia] = true;
            // add i to pattern of C
            cindex.push(ia);
            // x(ia) = A
            x[ia] = mf(vbi, avalues[ka]);
          } else {
            // i exists in C already
            x[ia] = af(x[ia], mf(vbi, avalues[ka]));
          }
        }
      }
    }
    // copy values from x to column jb of c
    for (let p1 = cindex.length, p = 0; p < p1; p++) {
      // row
      const ic = cindex[p];
      // copy value
      cvalues[p] = x[ic];
    }
    // update ptr
    cptr[1] = cindex.length;

    // matrix to return
    return a.createSparseMatrix({
      values: cvalues,
      index: cindex,
      ptr: cptr,
      size: [arows, 1],
      datatype: adt === a._datatype && bdt === b._datatype ? dt : undefined
    });
  }

  /**
   * C = A * B
   *
   * @param {Matrix} a            SparseMatrix      (MxN)
   * @param {Matrix} b            DenseMatrix       (NxC)
   *
   * @return {Matrix}             SparseMatrix      (MxC)
   */
  function _multiplySparseMatrixDenseMatrix(a, b) {
    // a sparse
    const avalues = a._values;
    const aindex = a._index;
    const aptr = a._ptr;
    const adt = a._datatype || a._data === undefined ? a._datatype : a.getDataType();
    // validate a matrix
    if (!avalues) {
      throw new Error('Cannot multiply Pattern only Matrix times Dense Matrix');
    }
    // b dense
    const bdata = b._data;
    const bdt = b._datatype || b.getDataType();
    // rows & columns
    const arows = a._size[0];
    const brows = b._size[0];
    const bcolumns = b._size[1];

    // datatype
    let dt;
    // addScalar signature to use
    let af = addScalar;
    // multiplyScalar signature to use
    let mf = multiplyScalar;
    // equalScalar signature to use
    let eq = equalScalar;
    // zero value
    let zero = 0;

    // process data types
    if (adt && bdt && adt === bdt && typeof adt === 'string' && adt !== 'mixed') {
      // datatype
      dt = adt;
      // find signatures that matches (dt, dt)
      af = typed.find(addScalar, [dt, dt]);
      mf = typed.find(multiplyScalar, [dt, dt]);
      eq = typed.find(equalScalar, [dt, dt]);
      // convert 0 to the same datatype
      zero = typed.convert(0, dt);
    }

    // result
    const cvalues = [];
    const cindex = [];
    const cptr = [];
    // c matrix
    const c = a.createSparseMatrix({
      values: cvalues,
      index: cindex,
      ptr: cptr,
      size: [arows, bcolumns],
      datatype: adt === a._datatype && bdt === b._datatype ? dt : undefined
    });

    // workspace
    const x = [];
    // vector with marks indicating a value x[i] exists in a given column
    const w = [];

    // loop b columns
    for (let jb = 0; jb < bcolumns; jb++) {
      // update ptr
      cptr[jb] = cindex.length;
      // mark in workspace for current column
      const mark = jb + 1;
      // rows in jb
      for (let ib = 0; ib < brows; ib++) {
        // b[ib, jb]
        const vbij = bdata[ib][jb];
        // check b[ib, jb] != 0, avoid loops
        if (!eq(vbij, zero)) {
          // A values & index in ib column
          for (let ka0 = aptr[ib], ka1 = aptr[ib + 1], ka = ka0; ka < ka1; ka++) {
            // a row
            const ia = aindex[ka];
            // check value exists in current j
            if (w[ia] !== mark) {
              // ia is new entry in j
              w[ia] = mark;
              // add i to pattern of C
              cindex.push(ia);
              // x(ia) = A
              x[ia] = mf(vbij, avalues[ka]);
            } else {
              // i exists in C already
              x[ia] = af(x[ia], mf(vbij, avalues[ka]));
            }
          }
        }
      }
      // copy values from x to column jb of c
      for (let p0 = cptr[jb], p1 = cindex.length, p = p0; p < p1; p++) {
        // row
        const ic = cindex[p];
        // copy value
        cvalues[p] = x[ic];
      }
    }
    // update ptr
    cptr[bcolumns] = cindex.length;

    // return sparse matrix
    return c;
  }

  /**
   * C = A * B
   *
   * @param {Matrix} a            SparseMatrix      (MxN)
   * @param {Matrix} b            SparseMatrix      (NxC)
   *
   * @return {Matrix}             SparseMatrix      (MxC)
   */
  function _multiplySparseMatrixSparseMatrix(a, b) {
    // a sparse
    const avalues = a._values;
    const aindex = a._index;
    const aptr = a._ptr;
    const adt = a._datatype || a._data === undefined ? a._datatype : a.getDataType();
    // b sparse
    const bvalues = b._values;
    const bindex = b._index;
    const bptr = b._ptr;
    const bdt = b._datatype || b._data === undefined ? b._datatype : b.getDataType();

    // rows & columns
    const arows = a._size[0];
    const bcolumns = b._size[1];
    // flag indicating both matrices (a & b) contain data
    const values = avalues && bvalues;

    // datatype
    let dt;
    // addScalar signature to use
    let af = addScalar;
    // multiplyScalar signature to use
    let mf = multiplyScalar;

    // process data types
    if (adt && bdt && adt === bdt && typeof adt === 'string' && adt !== 'mixed') {
      // datatype
      dt = adt;
      // find signatures that matches (dt, dt)
      af = typed.find(addScalar, [dt, dt]);
      mf = typed.find(multiplyScalar, [dt, dt]);
    }

    // result
    const cvalues = values ? [] : undefined;
    const cindex = [];
    const cptr = [];
    // c matrix
    const c = a.createSparseMatrix({
      values: cvalues,
      index: cindex,
      ptr: cptr,
      size: [arows, bcolumns],
      datatype: adt === a._datatype && bdt === b._datatype ? dt : undefined
    });

    // workspace
    const x = values ? [] : undefined;
    // vector with marks indicating a value x[i] exists in a given column
    const w = [];
    // variables
    let ka, ka0, ka1, kb, kb0, kb1, ia, ib;
    // loop b columns
    for (let jb = 0; jb < bcolumns; jb++) {
      // update ptr
      cptr[jb] = cindex.length;
      // mark in workspace for current column
      const mark = jb + 1;
      // B values & index in j
      for (kb0 = bptr[jb], kb1 = bptr[jb + 1], kb = kb0; kb < kb1; kb++) {
        // b row
        ib = bindex[kb];
        // check we need to process values
        if (values) {
          // loop values in a[:,ib]
          for (ka0 = aptr[ib], ka1 = aptr[ib + 1], ka = ka0; ka < ka1; ka++) {
            // row
            ia = aindex[ka];
            // check value exists in current j
            if (w[ia] !== mark) {
              // ia is new entry in j
              w[ia] = mark;
              // add i to pattern of C
              cindex.push(ia);
              // x(ia) = A
              x[ia] = mf(bvalues[kb], avalues[ka]);
            } else {
              // i exists in C already
              x[ia] = af(x[ia], mf(bvalues[kb], avalues[ka]));
            }
          }
        } else {
          // loop values in a[:,ib]
          for (ka0 = aptr[ib], ka1 = aptr[ib + 1], ka = ka0; ka < ka1; ka++) {
            // row
            ia = aindex[ka];
            // check value exists in current j
            if (w[ia] !== mark) {
              // ia is new entry in j
              w[ia] = mark;
              // add i to pattern of C
              cindex.push(ia);
            }
          }
        }
      }
      // check we need to process matrix values (pattern matrix)
      if (values) {
        // copy values from x to column jb of c
        for (let p0 = cptr[jb], p1 = cindex.length, p = p0; p < p1; p++) {
          // row
          const ic = cindex[p];
          // copy value
          cvalues[p] = x[ic];
        }
      }
    }
    // update ptr
    cptr[bcolumns] = cindex.length;

    // return sparse matrix
    return c;
  }

  /**
   * Multiply two or more values, `x * y`.
   * For matrices, the matrix product is calculated.
   *
   * Syntax:
   *
   *    math.multiply(x, y)
   *    math.multiply(x, y, z, ...)
   *
   * Examples:
   *
   *    math.multiply(4, 5.2)        // returns number 20.8
   *    math.multiply(2, 3, 4)       // returns number 24
   *
   *    const a = math.complex(2, 3)
   *    const b = math.complex(4, 1)
   *    math.multiply(a, b)          // returns Complex 5 + 14i
   *
   *    const c = [[1, 2], [4, 3]]
   *    const d = [[1, 2, 3], [3, -4, 7]]
   *    math.multiply(c, d)          // returns Array [[7, -6, 17], [13, -4, 33]]
   *
   *    const e = math.unit('2.1 km')
   *    math.multiply(3, e)          // returns Unit 6.3 km
   *
   * See also:
   *
   *    divide, prod, cross, dot
   *
   * @param  {number | BigNumber | bigint | Fraction | Complex | Unit | Array | Matrix} x First value to multiply
   * @param  {number | BigNumber | bigint | Fraction | Complex | Unit | Array | Matrix} y Second value to multiply
   * @return {number | BigNumber | bigint | Fraction | Complex | Unit | Array | Matrix} Multiplication of `x` and `y`
   */
  return typed(name, multiplyScalar, {
    // we extend the signatures of multiplyScalar with signatures dealing with matrices

    'Array, Array': typed.referTo('Matrix, Matrix', selfMM => (x, y) => {
      // check dimensions
      _validateMatrixDimensions((0, _array.arraySize)(x), (0, _array.arraySize)(y));

      // use dense matrix implementation
      const m = selfMM(matrix(x), matrix(y));
      // return array or scalar
      return (0, _is.isMatrix)(m) ? m.valueOf() : m;
    }),
    'Matrix, Matrix': function (x, y) {
      // dimensions
      const xsize = x.size();
      const ysize = y.size();

      // check dimensions
      _validateMatrixDimensions(xsize, ysize);

      // process dimensions
      if (xsize.length === 1) {
        // process y dimensions
        if (ysize.length === 1) {
          // Vector * Vector
          return _multiplyVectorVector(x, y, xsize[0]);
        }
        // Vector * Matrix
        return _multiplyVectorMatrix(x, y);
      }
      // process y dimensions
      if (ysize.length === 1) {
        // Matrix * Vector
        return _multiplyMatrixVector(x, y);
      }
      // Matrix * Matrix
      return _multiplyMatrixMatrix(x, y);
    },
    'Matrix, Array': typed.referTo('Matrix,Matrix', selfMM => (x, y) => selfMM(x, matrix(y))),
    'Array, Matrix': typed.referToSelf(self => (x, y) => {
      // use Matrix * Matrix implementation
      return self(matrix(x, y.storage()), y);
    }),
    'SparseMatrix, any': function (x, y) {
      return matAlgo11xS0s(x, y, multiplyScalar, false);
    },
    'DenseMatrix, any': function (x, y) {
      return matAlgo14xDs(x, y, multiplyScalar, false);
    },
    'any, SparseMatrix': function (x, y) {
      return matAlgo11xS0s(y, x, multiplyScalar, true);
    },
    'any, DenseMatrix': function (x, y) {
      return matAlgo14xDs(y, x, multiplyScalar, true);
    },
    'Array, any': function (x, y) {
      // use matrix implementation
      return matAlgo14xDs(matrix(x), y, multiplyScalar, false).valueOf();
    },
    'any, Array': function (x, y) {
      // use matrix implementation
      return matAlgo14xDs(matrix(y), x, multiplyScalar, true).valueOf();
    },
    'any, any': multiplyScalar,
    'any, any, ...any': typed.referToSelf(self => (x, y, rest) => {
      let result = self(x, y);
      for (let i = 0; i < rest.length; i++) {
        result = self(result, rest[i]);
      }
      return result;
    })
  });
});