NAME
    Statistics::Descriptive::Discrete - Compute descriptive statistics for
    discrete data sets.

    To install, use the CPAN module
    (https://metacpan.org/pod/Statistics::Descriptive::Discrete).

SYNOPSIS
      use Statistics::Descriptive::Discrete;

      my $stats = new Statistics::Descriptive::Discrete;
      $stats->add_data(1,10,2,1,1,4,5,1,10,8,7);
      print "count = ",$stats->count(),"\n";
      print "uniq  = ",$stats->uniq(),"\n";
      print "sum = ",$stats->sum(),"\n";
      print "min = ",$stats->min(),"\n";
      print "min index = ",$stats->mindex(),"\n";
      print "max = ",$stats->max(),"\n";
      print "max index = ",$stats->maxdex(),"\n";
      print "mean = ",$stats->mean(),"\n";
      print "geometric mean = ",$stats->geometric_mean(),"\n";
      print "harmonic mean = ", $stats->harmonic_mean(),"\n";
      print "standard_deviation = ",$stats->standard_deviation(),"\n";
      print "variance = ",$stats->variance(),"\n";
      print "sample_range = ",$stats->sample_range(),"\n";
      print "mode = ",$stats->mode(),"\n";
      print "median = ",$stats->median(),"\n";
      my $f = $stats->frequency_distribution_ref(3);
      for (sort {$a <=> $b} keys %$f) {
        print "key = $_, count = $f->{$_}\n";
      }

DESCRIPTION
    This module provides basic functions used in descriptive statistics. It
    borrows very heavily from Statistics::Descriptive::Full (which is
    included with Statistics::Descriptive) with one major difference. This
    module is optimized for discretized data e.g. data from an A/D
    conversion that has a discrete set of possible values. E.g. if your data
    is produced by an 8 bit A/D then you'd have only 256 possible values in
    your data set. Even though you might have a million data points, you'd
    only have 256 different values in those million points. Instead of
    storing the entire data set as Statistics::Descriptive does, this module
    only stores the values seen and the number of times each value occurs.

    For very large data sets, this storage method results in significant
    speed and memory improvements. For example, for an 8-bit data set (256
    possible values), with 1,000,000 data points, this module is about 10x
    faster than Statistics::Descriptive::Full or
    Statistics::Descriptive::Sparse.

    Statistics::Descriptive run time is a factor of the size of the data
    set. In particular, repeated calls to `add_data' are slow.
    Statistics::Descriptive::Discrete's `add_data' is optimized for speed.
    For a give number of data points, this module's run time will increase
    as the number of unique data values in the data set increases. For
    example, while this module runs about 10x the speed of
    Statistics::Descriptive::Full for an 8-bit data set, the run speed drops
    to about 3x for an equivalent sized 20-bit data set.

    See sdd_prof.pl in the examples directory to play with profiling this
    module against Statistics::Descriptive::Full.

METHODS
    $stat = Statistics::Descriptive::Discrete->new();
        Create a new statistics object.

    $stat->add_data(1,2,3,4,5);
        Adds data to the statistics object. Sets a flag so that the
        statistics will be recomputed the next time they're needed.

    $stat->add_data_tuple(1,2,42,3);
        Adds data to the statistics object where every two elements are a
        value and a count (how many times did the value occur?) The above is
        equivalent to `$stat->add_data(1,1,42,42,42);' Use this when your
        data is in a form isomorphic to ($value, $occurrence).

    $stat->max();
        Returns the maximum value of the data set.

    $stat->min();
        Returns the minimum value of the data set.

    $stat->mindex();
        Returns the index of the minimum value of the data set. The index
        returned is the first occurence of the minimum value.

        Note: the index is determined by the order data was added using
        add_data() or add_data_tuple(). It is meaningless in context of
        get_data() as get_data() does not return values in the same order in
        which they were added. This behavior is different than
        Statistics::Descriptive which does preserve order.

    $stat->maxdex();
        Returns the index of the maximum value of the data set. The index
        returned is the first occurence of the maximum value.

        Note: the index is determined by the order data was added using
        `add_data()' or `add_data_tuple()'. It is meaningless in context of
        `get_data()' as `get_data()' does not return values in the same
        order in which they were added. This behavior is different than
        Statistics::Descriptive which does preserve order.

    $stat->count();
        Returns the total number of elements in the data set.

    $stat->uniq();
        If called in scalar context, returns the total number of unique
        elements in the data set. For example, if your data set is
        (1,2,2,3,3,3), uniq will return 3.

        If called in array context, returns an array of each data value in
        the data set in sorted order. In the above example, `@uniq =
        $stats->uniq();' would return (1,2,3)

        This function is specific to Statistics::Descriptive::Discrete and
        is not implemented in Statistics::Descriptive.

        It is useful for getting a frequency distribution for each discrete
        value in the data the set:

           my $stats = Statistics::Descriptive::Discrete->new();
                 $stats->add_data_tuple(1,1,2,2,3,3,4,4,5,5,6,6,7,7);
                 my @bins = $stats->uniq();
                 my $f = $stats->frequency_distribution_ref(\@bins);
                 for (sort {$a <=> $b} keys %$f) {
                         print "value = $_, count = $f->{$_}\n";
                 }

    $stat->sum();
        Returns the sum of all the values in the data set.

    $stat->mean();
        Returns the mean of the data.

    $stat->harmonic_mean();
        Returns the harmonic mean of the data. Since the mean is undefined
        if any of the data are zero or if the sum of the reciprocals is
        zero, it will return undef for both of those cases.

    $stat->geometric_mean();
        Returns the geometric mean of the data. Returns `undef' if any of
        the data are less than 0. Returns 0 if any of the data are 0.

    $stat->median();
        Returns the median value of the data.

    $stat->mode();
        Returns the mode of the data.

    $stat->variance();
        Returns the variance of the data.

    $stat->standard_deviation();
        Returns the standard_deviation of the data.

    $stat->sample_range();
        Returns the sample range (max - min) of the data set.

    $stat->frequency_distribution_ref($num_partitions);
    $stat->frequency_distribution_ref(\@bins);
    $stat->frequency_distribution_ref();
        `frequency_distribution_ref($num_partitions)' slices the data into
        `$num_partitions' sets (where $num_partitions is greater than 1) and
        counts the number of items that fall into each partition. It returns
        a reference to a hash where the keys are the numerical values of the
        partitions used. The minimum value of the data set is not a key and
        the maximum value of the data set is always a key. The number of
        entries for a particular partition key are the number of items which
        are greater than the previous partition key and less then or equal
        to the current partition key. As an example,

           $stat->add_data(1,1.5,2,2.5,3,3.5,4);
           $f = $stat->frequency_distribution_ref(2);
           for (sort {$a <=> $b} keys %$f) {
              print "key = $_, count = $f->{$_}\n";
           }

        prints

           key = 2.5, count = 4
           key = 4, count = 3

        since there are four items less than or equal to 2.5, and 3 items
        greater than 2.5 and less than 4.

        `frequency_distribution_ref(\@bins)' provides the bins that are to
        be used for the distribution. This allows for non-uniform
        distributions as well as trimmed or sample distributions to be
        found. `@bins' must be monotonic and must contain at least one
        element. Note that unless the set of bins contains the full range of
        the data, the total counts returned will be less than the sample
        size.

        Calling `frequency_distribution_ref()' with no arguments returns the
        last distribution calculated, if such exists.

    my %hash = $stat->frequency_distribution($partitions);
    my %hash = $stat->frequency_distribution(\@bins);
    my %hash = $stat->frequency_distribution();
        Same as `frequency_distribution_ref()' except that it returns the
        hash clobbered into the return list. Kept for compatibility reasons
        with previous versions of Statistics::Descriptive::Discrete and
        using it is discouraged.

        Note: in earlier versions of Statistics:Descriptive::Discrete,
        `frequency_distribution()' behaved differently than the
        Statistics::Descriptive implementation. Any code that uses this
        function should be carefully checked to ensure compatability with
        the current implementation.

    $stat->get_data();
        Returns a copy of the data array. Note: This array could be very
        large and would thus defeat the purpose of using this module. Make
        sure you really need it before using get_data().

        The returned array contains the values sorted by value. It does not
        preserve the order in which the values were added. Preserving order
        would defeat the purpose of this module which trades speed and
        memory usage over preserving order. If order is important, use
        Statistics::Descriptive.

    $stat->clear();
        Clears all data and resets the instance as if it were newly created

        Effectively the same as

          my $class = ref($stat);
          undef $stat;
          $stat = new $class;

NOTE
    The interface for this module strives to be identical to
    Statistics::Descriptive. Any differences are noted in the description
    for each method.

BUGS
    *   Code for calculating mode is not as robust as it should be.

TODO
    *   Add rest of methods (at least ones that don't depend on original
        order of data) from Statistics::Descriptive

AUTHOR
    Rhet Turnbull, rturnbull+cpan@gmail.com

CREDIT
    Thanks to the following individuals for finding bugs, providing
    feedback, and submitting changes:

    *   Peter Dienes for finding and fixing a bug in the variance
        calculation.

    *   Bill Dueber for suggesting the add_data_tuple method.

COPYRIGHT
      Copyright (c) 2002, 2019 Rhet Turnbull. All rights reserved.  This
      program is free software; you can redistribute it and/or modify it
      under the same terms as Perl itself.

      Portions of this code is from Statistics::Descriptive which is under
      the following copyrights:

      Copyright (c) 1997,1998 Colin Kuskie. All rights reserved.  This
      program is free software; you can redistribute it and/or modify it
      under the same terms as Perl itself.

      Copyright (c) 1998 Andrea Spinelli. All rights reserved.  This program
      is free software; you can redistribute it and/or modify it under the
      same terms as Perl itself.

      Copyright (c) 1994,1995 Jason Kastner. All rights
      reserved.  This program is free software; you can redistribute it
      and/or modify it under the same terms as Perl itself.

SEE ALSO
    Statistics::Descriptive

    Statistics::Discrete