flops.jl

import Printf.@printf

function dtime(p)
    q = p[2]
    p[2] = time()
    p[1] = p[2] - q
end

function main()
    A0 = 1.0
    A1 = -0.1666666666671334
    A2 = 0.833333333809067E-2
    A3 = 0.198412715551283E-3
    A4 = 0.27557589750762E-5
    A5 = 0.2507059876207E-7
    A6 = 0.164105986683E-9

    B0 = 1.0
    B1 = -0.4999999999982
    B2 = 0.4166666664651E-1
    B3 = -0.1388888805755E-2
    B4 = 0.24801428034E-4
    B5 = -0.2754213324E-6
    B6 = 0.20189405E-8

    C0 = 1.0
    C1 = 0.99999999668
    C2 = 0.49999995173
    C3 = 0.16666704243
    C4 = 0.4166685027E-1
    C5 = 0.832672635E-2
    C6 = 0.140836136E-2
    C7 = 0.17358267E-3
    C8 = 0.3931683E-4

    D1 = 0.3999999946405E-1
    D2 = 0.96E-3
    D3 = 0.1233153E-5

    E2 = 0.48E-3
    E3 = 0.411051E-6

    s = 0.0
    u = 0.0
    v = 0.0
    w = 0.0
    x = 0.0

    println("   FLOPS Julia Program (Double Precision), V2.0 18 Dec 1992")

    T = zeros(Float64, 36)

    loops = 15625
    T[1] = 1.0E+06/loops

    TLimit = 15.0
    NLimit = 512000000

    piref = 3.14159265358979324
    one   = 1.0
    two   = 2.0
    three = 3.0
    four  = 4.0
    five  = 5.0
    scale = one

    println("   Module     Error        RunTime      MFLOPS")
    println("                            (usec)")
    TimeArray = Array{Float64}(undef,4)
    dtime(TimeArray)
    dtime(TimeArray)

#/*******************************************************/
#/* Module 1.  Calculate integral of df(x)/f(x) defined */
#/*            below.  Result is ln(f(1)). There are 14 */
#/*            double precision operations per loop     */
#/*            ( 7 +, 0 -, 6 *, 1 / ) that are included */
#/*            in the timing.                           */
#/*            50.0% +, 00.0% -, 42.9% *, and 07.1% /   */
#/*******************************************************/
    n = loops
    sa = 0.0
    while sa < TLimit
        n = 2 * n
        x = one / n    #                        /*********************/
        s = 0.0                #                        /*  Loop 1.          */
        v = 0.0                #                        /*********************/
        w = one 

        dtime(TimeArray)
        for i in 1:n
            v = v + w
            u = v * x
            s = s + (D1+u*(D2+u*D3))/(w+u*(D1+u*(E2+u*E3)))
        end
        dtime(TimeArray)
        sa = TimeArray[1]

        if n == NLimit
            break
            #/* printf(" %10ld  %12.5lf\n",n,sa); */
        end
    end

    scale = 1.0E+06 / n
    T[1]  = scale
#/****************************************/
#/* Estimate nulltime ('for' loop time). */
    #/****************************************/
    dtime(TimeArray)
    for i in 1:n
    end
    dtime(TimeArray)
    nulltime = T[1] * TimeArray[1]
    if nulltime < 0.0
        nulltime = 0.0
    end

    T[2] = T[1] * sa - nulltime

    sa = (D1+D2+D3)/(one+D1+E2+E3)
    sb = D1

    T[3] = T[2] / 14.0#                             /*********************/
    sa = x * ( sa + sb + two * s ) / two#           /* Module 1 Results. */
    sb = one / sa#                                  /*********************/
    n  = round( ( 40000 * sb ) / scale )
    sc = sb - 25.2
    T[4] = one / T[3]
    #						   /********************/
    #						   /*  DO NOT REMOVE   */
    #						   /*  THIS PRINTOUT!  */
    #						   /********************/
    #//   printf("     1   %13.4le  %10.4lf  %10.4lf\n",sc,T[2],T[4])
    @printf( "     1   %13.4e  %10.4f  %10.4f\n", sc,T[2],T[4])

    m = n
#/*******************************************************/
#/* Module 2.  Calculate value of PI from Taylor Series */
#/*            expansion of atan(1.0).  There are 7     */
#/*            double precision operations per loop     */
#/*            ( 3 +, 2 -, 1 *, 1 / ) that are included */
#/*            in the timing.                           */
#/*            42.9% +, 28.6% -, 14.3% *, and 14.3% /   */
#/*******************************************************/

    s  = -five#                                      /********************/
    sa = -one#                                       /* Loop 2.          */
#						   /********************/
    dtime(TimeArray)
    for i in 1:m+1
        s  = -s
        sa = sa + s
    end
    dtime(TimeArray)
    T[5] = T[1] * TimeArray[1]
    if T[5] < 0.0
        T[5] = 0.0
    end

    sc   = m

    u = sa#                                         /*********************/
    v = 0.0#                                        /* Loop 3.           */
    w = 0.0#                                        /*********************/
    x = 0.0

    dtime(TimeArray)
    for i in 1:m+1
        s  = -s
        sa = sa + s
        u  = u + two
        x  = x +(s - u)
        v  = v - s * u
        w  = w + s / u
    end
    dtime(TimeArray)
    T[6] = T[1] * TimeArray[1]

    T[7] = ( T[6] - T[5] ) / 7.0#                   /*********************/
    m  = round( sa * x  / sc )#                    /*  PI Results       */
    sa = four * w / five#                           /*********************/
    sb = sa + five / v
    sc = 31.25
    piprg = sb - sc / (v * v * v)
    pierr = piprg - piref
    T[8] = one  / T[7]
#						  /*********************/
#						  /*   DO NOT REMOVE   */
#						  /*   THIS PRINTOUT!  */
#						  /*********************/
    @printf("     2   %13.4e  %10.4f  %10.4f\n", pierr,T[6]-T[5],T[8])
    
#/*******************************************************/
#/* Module 3.  Calculate integral of sin(x) from 0.0 to */
#/*            PI/3.0 using Trapazoidal Method. Result  */
#/*            is 0.5. There are 17 double precision    */
#/*            operations per loop (6 +, 2 -, 9 *, 0 /) */
#/*            included in the timing.                  */
#/*            35.3% +, 11.8% -, 52.9% *, and 00.0% /   */
#/*******************************************************/

    x = piref / ( three * m )#              /*********************/
    s = 0.0#                                        /*  Loop 4.          */
    v = 0.0#                                        /*********************/

    dtime(TimeArray)
    for i in 1:m
        v = v + one
        u = v * x
        w = u * u
        s = s + u * ((((((A6*w-A5)*w+A4)*w-A3)*w+A2)*w+A1)*w+one)
    end
    dtime(TimeArray)
    T[9]  = T[1] * TimeArray[1] - nulltime

    u  = piref / three
    w  = u * u
    sa = u * ((((((A6*w-A5)*w+A4)*w-A3)*w+A2)*w+A1)*w+one)

    T[10] = T[9] / 17.0#                            /*********************/
    sa = x * ( sa + two * s ) / two#                /* sin(x) Results.   */
    sb = 0.5#                                       /*********************/
    sc = sa - sb
    T[11] = one / T[10]
#						  /*********************/
#						  /*   DO NOT REMOVE   */
#						  /*   THIS PRINTOUT!  */
#						  /*********************/
    @printf("     3   %13.4e  %10.4f  %10.4f\n", sc,T[9],T[11])

#/************************************************************/
#/* Module 4.  Calculate Integral of cos(x) from 0.0 to PI/3 */
#/*            using the Trapazoidal Method. Result is       */
#/*            sin(PI/3). There are 15 double precision      */
#/*            operations per loop (7 +, 0 -, 8 *, and 0 / ) */
#/*            included in the timing.                       */
#/*            50.0% +, 00.0% -, 50.0% *, 00.0% /            */
#/************************************************************/
   A3 = -A3
   A5 = -A5
   x = piref / ( three * m )#              /*********************/
   s = 0.0#                                        /*  Loop 5.          */
   v = 0.0#                                        /*********************/

   dtime(TimeArray)
   for i in 1:m
       u = i * x
       w = u * u
       s = s + w*(w*(w*(w*(w*(B6*w+B5)+B4)+B3)+B2)+B1)+one
   end
   dtime(TimeArray)
   T[12]  = T[1] * TimeArray[1] - nulltime

   u  = piref / three
   w  = u * u
   sa = w*(w*(w*(w*(w*(B6*w+B5)+B4)+B3)+B2)+B1)+one

   T[13] = T[12] / 15.0#                             /*******************/
   sa = x * ( sa + one + two * s ) / two#            /* Module 4 Result */
   u  = piref / three#                               /*******************/
   w  = u * u
   sb = u * ((((((A6*w+A5)*w+A4)*w+A3)*w+A2)*w+A1)*w+A0)
   sc = sa - sb
   T[14] = one / T[13]
#						  /*********************/
#						  /*   DO NOT REMOVE   */
#						  /*   THIS PRINTOUT!  */
#						  /*********************/
   @printf("     4   %13.4e  %10.4f  %10.4f\n", sc,T[12],T[14])

#/************************************************************/
#/* Module 5.  Calculate Integral of tan(x) from 0.0 to PI/3 */
#/*            using the Trapazoidal Method. Result is       */
#/*            ln(cos(PI/3)). There are 29 double precision  */
#/*            operations per loop (13 +, 0 -, 15 *, and 1 /)*/
#/*            included in the timing.                       */
#/*            46.7% +, 00.0% -, 50.0% *, and 03.3% /        */
#/************************************************************/

   x = piref / ( three * m )#              /*********************/
   s = 0.0#                                        /*  Loop 6.          */
   v = 0.0#                                        /*********************/

   dtime(TimeArray)
   for i in 1:m
      u = i * x
      w = u * u
      v = u * ((((((A6*w+A5)*w+A4)*w+A3)*w+A2)*w+A1)*w+one)
       s = s + v / (w*(w*(w*(w*(w*(B6*w+B5)+B4)+B3)+B2)+B1)+one)
   end
   dtime(TimeArray)
   T[15]  = T[1] * TimeArray[1] - nulltime

   u  = piref / three
   w  = u * u
   sa = u*((((((A6*w+A5)*w+A4)*w+A3)*w+A2)*w+A1)*w+one)
   sb = w*(w*(w*(w*(w*(B6*w+B5)+B4)+B3)+B2)+B1)+one
   sa = sa / sb

   T[16] = T[15] / 29.0#                             /*******************/
   sa = x * ( sa + two * s ) / two#                  /* Module 5 Result */
   sb = 0.6931471805599453#                          /*******************/
   sc = sa - sb
   T[17] = one / T[16]
#						  /*********************/
#						  /*   DO NOT REMOVE   */
#						  /*   THIS PRINTOUT!  */
#						  /*********************/
   @printf("     5   %13.4e  %10.4f  %10.4f\n", sc,T[15],T[17])

#/************************************************************/
#/* Module 6.  Calculate Integral of sin(x)*cos(x) from 0.0  */
#/*            to PI/4 using the Trapazoidal Method. Result  */
#/*            is sin(PI/4)^2. There are 29 double precision */
#/*            operations per loop (13 +, 0 -, 16 *, and 0 /)*/
#/*            included in the timing.                       */
#/*            46.7% +, 00.0% -, 53.3% *, and 00.0% /        */
#/************************************************************/

   x = piref / ( four * m )#               /*********************/
   s = 0.0#                                        /*  Loop 7.          */
   v = 0.0#                                        /*********************/

   dtime(TimeArray)
   for i in 1:m
      u = i * x
      w = u * u
      v = u * ((((((A6*w+A5)*w+A4)*w+A3)*w+A2)*w+A1)*w+one)
       s = s + v*(w*(w*(w*(w*(w*(B6*w+B5)+B4)+B3)+B2)+B1)+one)
   end
   dtime(TimeArray)
   T[18]  = T[1] * TimeArray[1] - nulltime

   u  = piref / four
   w  = u * u
   sa = u*((((((A6*w+A5)*w+A4)*w+A3)*w+A2)*w+A1)*w+one)
   sb = w*(w*(w*(w*(w*(B6*w+B5)+B4)+B3)+B2)+B1)+one
   sa = sa * sb

   T[19] = T[18] / 29.0#                             /*******************/
   sa = x * ( sa + two * s ) / two#                  /* Module 6 Result */
   sb = 0.25#                                        /*******************/
   sc = sa - sb
   T[20] = one / T[19]
#						  /*********************/
#						  /*   DO NOT REMOVE   */
#						  /*   THIS PRINTOUT!  */
#						  /*********************/
   @printf("     6   %13.4e  %10.4f  %10.4f\n",sc,T[18],T[20])


#/*******************************************************/
#/* Module 7.  Calculate value of the definite integral */
#/*            from 0 to sa of 1/(x+1), x/(x*x+1), and  */
#/*            x*x/(x*x*x+1) using the Trapizoidal Rule.*/
#/*            There are 12 double precision operations */
#/*            per loop ( 3 +, 3 -, 3 *, and 3 / ) that */
#/*            are included in the timing.              */
#/*            25.0% +, 25.0% -, 25.0% *, and 25.0% /   */
#/*******************************************************/

#                                                  /*********************/
   s = 0.0#                                        /* Loop 8.           */
   w = one#                                        /*********************/
   sa = 102.3321513995275
   v = sa / m

   dtime(TimeArray)
   for i in 1:m
      x = i * v
      u = x * x
       s = s - w / ( x + w ) - x / ( u + w ) - u / ( x * u + w )
   end
   dtime(TimeArray)
   T[21] = T[1] * TimeArray[1] - nulltime
#						  /*********************/
#						  /* Module 7 Results  */
#						  /*********************/
   T[22] = T[21] / 12.0                                  
   x  = sa                                      
   u  = x * x
   sa = -w - w / ( x + w ) - x / ( u + w ) - u / ( x * u + w )
   sa = 18.0 * v * (sa + two * s )

   m  = -2000 * round(sa)
   m = round( m / scale )

   sc = sa + 500.2
   T[23] = one / T[22]
#						  /********************/
#						  /*  DO NOT REMOVE   */
#						  /*  THIS PRINTOUT!  */
#						  /********************/
   @printf("     7   %13.4e  %10.4f  %10.4f\n", sc,T[21],T[23])

#/************************************************************/
#/* Module 8.  Calculate Integral of sin(x)*cos(x)*cos(x)    */
#/*            from 0 to PI/3 using the Trapazoidal Method.  */
#/*            Result is (1-cos(PI/3)^3)/3. There are 30     */
#/*            double precision operations per loop included */
#/*            in the timing:                                */
#/*               13 +,     0 -,    17 *          0 /        */
#/*            46.7% +, 00.0% -, 53.3% *, and 00.0% /        */
#/************************************************************/

   x = piref / ( three * m )#              /*********************/
   s = 0.0#                                        /*  Loop 9.          */
   v = 0.0#                                        /*********************/

   dtime(TimeArray)
   for i in 1:m
      u = i * x
      w = u * u
      v = w*(w*(w*(w*(w*(B6*w+B5)+B4)+B3)+B2)+B1)+one
       s = s + v*v*u*((((((A6*w+A5)*w+A4)*w+A3)*w+A2)*w+A1)*w+one)
   end
   dtime(TimeArray)
   T[24]  = T[1] * TimeArray[1] - nulltime

   u  = piref / three
   w  = u * u
   sa = u*((((((A6*w+A5)*w+A4)*w+A3)*w+A2)*w+A1)*w+one)
   sb = w*(w*(w*(w*(w*(B6*w+B5)+B4)+B3)+B2)+B1)+one
   sa = sa * sb * sb

   T[25] = T[24] / 30.0#                             /*******************/
   sa = x * ( sa + two * s ) / two#                  /* Module 8 Result */
   sb = 0.29166666666666667#                         /*******************/
   sc = sa - sb
   T[26] = one / T[25]
#						  /*********************/
#						  /*   DO NOT REMOVE   */
#						  /*   THIS PRINTOUT!  */
#						  /*********************/
   @printf("     8   %13.4e  %10.4f  %10.4f\n", sc,T[24],T[26])

#/**************************************************/   
#/* MFLOPS(1) output. This is the same weighting   */
#/* used for all previous versions of the flops.c  */
#/* program. Includes Modules 2 and 3 only.        */
#/**************************************************/ 
   T[27] = ( five * (T[6] - T[5]) + T[9] ) / 52.0
   T[28] = one  / T[27]

#/**************************************************/   
#/* MFLOPS(2) output. This output does not include */
#/* Module 2, but it still does 9.2% FDIV's.       */
#/**************************************************/ 
   T[29] = T[2] + T[9] + T[12] + T[15] + T[18]
   T[29] = (T[29] + four * T[21]) / 152.0
   T[30] = one / T[29]

#/**************************************************/   
#/* MFLOPS(3) output. This output does not include */
#/* Module 2, but it still does 3.4% FDIV's.       */
#/**************************************************/ 
   T[31] = T[2] + T[9] + T[12] + T[15] + T[18]
   T[31] = (T[31] + T[21] + T[24]) / 146.0
   T[32] = one / T[31]

#/**************************************************/   
#/* MFLOPS(4) output. This output does not include */
#/* Module 2, and it does NO FDIV's.               */
#/**************************************************/ 
   T[33] = (T[9] + T[12] + T[18] + T[24]) / 91.0
   T[34] = one / T[33]


   @printf("\n")
   @printf("   Iterations      = %10d\n", m)
   @printf("   NullTime (usec) = %10.4f\n", nulltime)
   @printf("   MFLOPS(1)       = %10.4f\n", T[28])
   @printf("   MFLOPS(2)       = %10.4f\n", T[30])
   @printf("   MFLOPS(3)       = %10.4f\n", T[32])
   @printf("   MFLOPS(4)       = %10.4f\n\n", T[34])

end

main()