Provided by: pdl_2.081-1_amd64 bug

NAME

       PDL::Primitive - primitive operations for pdl

DESCRIPTION

       This module provides some primitive and useful functions defined using PDL::PP and able to
       use the new indexing tricks.

       See PDL::Indexing for how to use indices creatively.  For explanation of the signature
       format, see PDL::PP.

SYNOPSIS

        # Pulls in PDL::Primitive, among other modules.
        use PDL;

        # Only pull in PDL::Primitive:
        use PDL::Primitive;

FUNCTIONS

   inner
         Signature: (a(n); b(n); [o]c())

       Inner product over one dimension

        c = sum_i a_i * b_i

       If "a() * b()" contains only bad data, "c()" is set bad. Otherwise "c()" will have its bad
       flag cleared, as it will not contain any bad values.

   outer
         Signature: (a(n); b(m); [o]c(n,m))

       outer product over one dimension

       Naturally, it is possible to achieve the effects of outer product simply by broadcasting
       over the ""*"" operator but this function is provided for convenience.

       outer processes bad values.  It will set the bad-value flag of all output ndarrays if the
       flag is set for any of the input ndarrays.

   x
        Signature: (a(i,z), b(x,i),[o]c(x,z))

       Matrix multiplication

       PDL overloads the "x" operator (normally the repeat operator) for matrix multiplication.
       The number of columns (size of the 0 dimension) in the left-hand argument must normally
       equal the number of rows (size of the 1 dimension) in the right-hand argument.

       Row vectors are represented as (N x 1) two-dimensional PDLs, or you may be sloppy and use
       a one-dimensional PDL.  Column vectors are represented as (1 x N) two-dimensional PDLs.

       Broadcasting occurs in the usual way, but as both the 0 and 1 dimension (if present) are
       included in the operation, you must be sure that you don't try to broadcast over either of
       those dims.

       Of note, due to how Perl v5.14.0 and above implement operator overloading of the "x"
       operator, the use of parentheses for the left operand creates a list context, that is

        pdl> ( $x * $y ) x $z
        ERROR: Argument "..." isn't numeric in repeat (x) ...

       treats $z as a numeric count for the list repeat operation and does not call the scalar
       form of the overloaded operator. To use the operator in this case, use a scalar context:

        pdl> scalar( $x * $y ) x $z

       or by calling "matmult" directly:

        pdl> ( $x * $y )->matmult( $z )

       EXAMPLES

       Here are some simple ways to define vectors and matrices:

        pdl> $r = pdl(1,2);                # A row vector
        pdl> $c = pdl([[3],[4]]);          # A column vector
        pdl> $c = pdl(3,4)->(*1);          # A column vector, using NiceSlice
        pdl> $m = pdl([[1,2],[3,4]]);      # A 2x2 matrix

       Now that we have a few objects prepared, here is how to matrix-multiply them:

        pdl> print $r x $m                 # row x matrix = row
        [
         [ 7 10]
        ]

        pdl> print $m x $r                 # matrix x row = ERROR
        PDL: Dim mismatch in matmult of [2x2] x [2x1]: 2 != 1

        pdl> print $m x $c                 # matrix x column = column
        [
         [ 5]
         [11]
        ]

        pdl> print $m x 2                  # Trivial case: scalar mult.
        [
         [2 4]
         [6 8]
        ]

        pdl> print $r x $c                 # row x column = scalar
        [
         [11]
        ]

        pdl> print $c x $r                 # column x row = matrix
        [
         [3 6]
         [4 8]
        ]

       INTERNALS

       The mechanics of the multiplication are carried out by the "matmult" method.

   matmult
         Signature: (a(t,h); b(w,t); [o]c(w,h))

       Matrix multiplication

       Notionally, matrix multiplication $x x $y is equivalent to the broadcasting expression

           $x->dummy(1)->inner($y->xchg(0,1)->dummy(2),$c);

       but for large matrices that breaks CPU cache and is slow.  Instead, matmult calculates its
       result in 32x32x32 tiles, to keep the memory footprint within cache as long as possible on
       most modern CPUs.

       For usage, see "x", a description of the overloaded 'x' operator

       matmult ignores the bad-value flag of the input ndarrays.  It will set the bad-value flag
       of all output ndarrays if the flag is set for any of the input ndarrays.

   innerwt
         Signature: (a(n); b(n); c(n); [o]d())

       Weighted (i.e. triple) inner product

        d = sum_i a(i) b(i) c(i)

       innerwt processes bad values.  It will set the bad-value flag of all output ndarrays if
       the flag is set for any of the input ndarrays.

   inner2
         Signature: (a(n); b(n,m); c(m); [o]d())

       Inner product of two vectors and a matrix

        d = sum_ij a(i) b(i,j) c(j)

       Note that you should probably not broadcast over "a" and "c" since that would be very
       wasteful. Instead, you should use a temporary for "b*c".

       inner2 processes bad values.  It will set the bad-value flag of all output ndarrays if the
       flag is set for any of the input ndarrays.

   inner2d
         Signature: (a(n,m); b(n,m); [o]c())

       Inner product over 2 dimensions.

       Equivalent to

        $c = inner($x->clump(2), $y->clump(2))

       inner2d processes bad values.  It will set the bad-value flag of all output ndarrays if
       the flag is set for any of the input ndarrays.

   inner2t
         Signature: (a(j,n); b(n,m); c(m,k); [t]tmp(n,k); [o]d(j,k)))

       Efficient Triple matrix product "a*b*c"

       Efficiency comes from by using the temporary "tmp". This operation only scales as "N**3"
       whereas broadcasting using "inner2" would scale as "N**4".

       The reason for having this routine is that you do not need to have the same broadcast-
       dimensions for "tmp" as for the other arguments, which in case of large numbers of
       matrices makes this much more memory-efficient.

       It is hoped that things like this could be taken care of as a kind of closures at some
       point.

       inner2t processes bad values.  It will set the bad-value flag of all output ndarrays if
       the flag is set for any of the input ndarrays.

   crossp
         Signature: (a(tri=3); b(tri); [o] c(tri))

       Cross product of two 3D vectors

       After

        $c = crossp $x, $y

       the inner product "$c*$x" and "$c*$y" will be zero, i.e. $c is orthogonal to $x and $y

       crossp does not process bad values.  It will set the bad-value flag of all output ndarrays
       if the flag is set for any of the input ndarrays.

   norm
         Signature: (vec(n); [o] norm(n))

       Normalises a vector to unit Euclidean length

       norm processes bad values.  It will set the bad-value flag of all output ndarrays if the
       flag is set for any of the input ndarrays.

   indadd
         Signature: (input(n); indx ind(n); [io] sum(m))

       Broadcasting index add: add "input" to the "ind" element of "sum", i.e:

        sum(ind) += input

       Simple example:

         $x = 2;
         $ind = 3;
         $sum = zeroes(10);
         indadd($x,$ind, $sum);
         print $sum
         #Result: ( 2 added to element 3 of $sum)
         # [0 0 0 2 0 0 0 0 0 0]

       Broadcasting example:

         $x = pdl( 1,2,3);
         $ind = pdl( 1,4,6);
         $sum = zeroes(10);
         indadd($x,$ind, $sum);
         print $sum."\n";
         #Result: ( 1, 2, and 3 added to elements 1,4,6 $sum)
         # [0 1 0 0 2 0 3 0 0 0]

       The routine barfs on bad indices, and bad inputs set target outputs bad.

   conv1d
         Signature: (a(m); kern(p); [o]b(m); int reflect)

       1D convolution along first dimension

       The m-th element of the discrete convolution of an input ndarray $a of size $M, and a
       kernel ndarray $kern of size $P, is calculated as

                                     n = ($P-1)/2
                                     ====
                                     \
         ($a conv1d $kern)[m]   =     >      $a_ext[m - n] * $kern[n]
                                     /
                                     ====
                                     n = -($P-1)/2

       where $a_ext is either the periodic (or reflected) extension of $a so it is equal to $a on
       " 0..$M-1 " and equal to the corresponding periodic/reflected image of $a outside that
       range.

         $con = conv1d sequence(10), pdl(-1,0,1);

         $con = conv1d sequence(10), pdl(-1,0,1), {Boundary => 'reflect'};

       By default, periodic boundary conditions are assumed (i.e. wrap around).  Alternatively,
       you can request reflective boundary conditions using the "Boundary" option:

         {Boundary => 'reflect'} # case in 'reflect' doesn't matter

       The convolution is performed along the first dimension. To apply it across another
       dimension use the slicing routines, e.g.

         $y = $x->mv(2,0)->conv1d($kernel)->mv(0,2); # along third dim

       This function is useful for broadcasted filtering of 1D signals.

       Compare also conv2d, convolve, fftconvolve, fftwconv, rfftwconv

       WARNING: "conv1d" processes bad values in its inputs as the numeric value of
       "$pdl->badvalue" so it is not recommended for processing pdls with bad values in them
       unless special care is taken.

       conv1d ignores the bad-value flag of the input ndarrays.  It will set the bad-value flag
       of all output ndarrays if the flag is set for any of the input ndarrays.

   in
         Signature: (a(); b(n); [o] c())

       test if a is in the set of values b

          $goodmsk = $labels->in($goodlabels);
          print pdl(3,1,4,6,2)->in(pdl(2,3,3));
         [1 0 0 0 1]

       "in" is akin to the is an element of of set theory. In principle, PDL broadcasting could
       be used to achieve its functionality by using a construct like

          $msk = ($labels->dummy(0) == $goodlabels)->orover;

       However, "in" doesn't create a (potentially large) intermediate and is generally faster.

       in does not process bad values.  It will set the bad-value flag of all output ndarrays if
       the flag is set for any of the input ndarrays.

   uniq
       return all unique elements of an ndarray

       The unique elements are returned in ascending order.

         PDL> p pdl(2,2,2,4,0,-1,6,6)->uniq
         [-1 0 2 4 6]     # 0 is returned 2nd (sorted order)

         PDL> p pdl(2,2,2,4,nan,-1,6,6)->uniq
         [-1 2 4 6 nan]   # NaN value is returned at end

       Note: The returned pdl is 1D; any structure of the input ndarray is lost.  "NaN" values
       are never compare equal to any other values, even themselves.  As a result, they are
       always unique. "uniq" returns the NaN values at the end of the result ndarray.  This
       follows the Matlab usage.

       See "uniqind" if you need the indices of the unique elements rather than the values.

       Bad values are not considered unique by uniq and are ignored.

        $x=sequence(10);
        $x=$x->setbadif($x%3);
        print $x->uniq;
        [0 3 6 9]

   uniqind
       Return the indices of all unique elements of an ndarray The order is in the order of the
       values to be consistent with uniq. "NaN" values never compare equal with any other value
       and so are always unique.  This follows the Matlab usage.

         PDL> p pdl(2,2,2,4,0,-1,6,6)->uniqind
         [5 4 1 3 6]     # the 0 at index 4 is returned 2nd, but...

         PDL> p pdl(2,2,2,4,nan,-1,6,6)->uniqind
         [5 1 3 6 4]     # ...the NaN at index 4 is returned at end

       Note: The returned pdl is 1D; any structure of the input ndarray is lost.

       See "uniq" if you want the unique values instead of the indices.

       Bad values are not considered unique by uniqind and are ignored.

   uniqvec
       Return all unique vectors out of a collection

         NOTE: If any vectors in the input ndarray have NaN values
         they are returned at the end of the non-NaN ones.  This is
         because, by definition, NaN values never compare equal with
         any other value.

         NOTE: The current implementation does not sort the vectors
         containing NaN values.

       The unique vectors are returned in lexicographically sorted ascending order. The 0th
       dimension of the input PDL is treated as a dimensional index within each vector, and the
       1st and any higher dimensions are taken to run across vectors. The return value is always
       2D; any structure of the input PDL (beyond using the 0th dimension for vector index) is
       lost.

       See also "uniq" for a unique list of scalars; and qsortvec for sorting a list of vectors
       lexicographcally.

       If a vector contains all bad values, it is ignored as in "uniq".  If some of the values
       are good, it is treated as a normal vector. For example, [1 2 BAD] and [BAD 2 3] could be
       returned, but [BAD BAD BAD] could not.  Vectors containing BAD values will be returned
       after any non-NaN and non-BAD containing vectors, followed by the NaN vectors.

   hclip
         Signature: (a(); b(); [o] c())

       clip (threshold) $a by $b ($b is upper bound)

       hclip processes bad values.  It will set the bad-value flag of all output ndarrays if the
       flag is set for any of the input ndarrays.

   lclip
         Signature: (a(); b(); [o] c())

       clip (threshold) $a by $b ($b is lower bound)

       lclip processes bad values.  It will set the bad-value flag of all output ndarrays if the
       flag is set for any of the input ndarrays.

   clip
       Clip (threshold) an ndarray by (optional) upper or lower bounds.

        $y = $x->clip(0,3);
        $c = $x->clip(undef, $x);

       clip handles bad values since it is just a wrapper around "hclip" and "lclip".

   clip
         Signature: (a(); l(); h(); [o] c())

       info not available

       clip processes bad values.  It will set the bad-value flag of all output ndarrays if the
       flag is set for any of the input ndarrays.

   wtstat
         Signature: (a(n); wt(n); avg(); [o]b(); int deg)

       Weighted statistical moment of given degree

       This calculates a weighted statistic over the vector "a".  The formula is

        b() = (sum_i wt_i * (a_i ** degree - avg)) / (sum_i wt_i)

       Bad values are ignored in any calculation; $b will only have its bad flag set if the
       output contains any bad data.

   statsover
         Signature: (a(n); w(n); float+ [o]avg(); float+ [o]prms(); int+ [o]median(); int+ [o]min(); int+ [o]max(); float+ [o]adev(); float+ [o]rms())

       Calculate useful statistics over a dimension of an ndarray

         ($mean,$prms,$median,$min,$max,$adev,$rms) = statsover($ndarray, $weights);

       This utility function calculates various useful quantities of an ndarray. These are:

       •  the mean:

            MEAN = sum (x)/ N

          with "N" being the number of elements in x

       •  the population RMS deviation from the mean:

            PRMS = sqrt( sum( (x-mean(x))^2 )/(N-1)

          The population deviation is the best-estimate of the deviation of the population from
          which a sample is drawn.

       •  the median

          The median is the 50th percentile data value.  Median is found by medover, so WEIGHTING
          IS IGNORED FOR THE MEDIAN CALCULATION.

       •  the minimum

       •  the maximum

       •  the average absolute deviation:

            AADEV = sum( abs(x-mean(x)) )/N

       •  RMS deviation from the mean:

            RMS = sqrt(sum( (x-mean(x))^2 )/N)

          (also known as the root-mean-square deviation, or the square root of the variance)

       This operator is a projection operator so the calculation will take place over the final
       dimension. Thus if the input is N-dimensional each returned value will be N-1 dimensional,
       to calculate the statistics for the entire ndarray either use "clump(-1)" directly on the
       ndarray or call "stats".

       Bad values are simply ignored in the calculation, effectively reducing the sample size.
       If all data are bad then the output data are marked bad.

   stats
       Calculates useful statistics on an ndarray

        ($mean,$prms,$median,$min,$max,$adev,$rms) = stats($ndarray,[$weights]);

       This utility calculates all the most useful quantities in one call.  It works the same way
       as "statsover", except that the quantities are calculated considering the entire input PDL
       as a single sample, rather than as a collection of rows. See "statsover" for definitions
       of the returned quantities.

       Bad values are handled; if all input values are bad, then all of the output values are
       flagged bad.

   histogram
         Signature: (in(n); int+[o] hist(m); double step; double min; int msize => m)

       Calculates a histogram for given stepsize and minimum.

        $h = histogram($data, $step, $min, $numbins);
        $hist = zeroes $numbins;  # Put histogram in existing ndarray.
        histogram($data, $hist, $step, $min, $numbins);

       The histogram will contain $numbins bins starting from $min, each $step wide. The value in
       each bin is the number of values in $data that lie within the bin limits.

       Data below the lower limit is put in the first bin, and data above the upper limit is put
       in the last bin.

       The output is reset in a different broadcastloop so that you can take a histogram of
       "$a(10,12)" into "$b(15)" and get the result you want.

       For a higher-level interface, see hist.

        pdl> p histogram(pdl(1,1,2),1,0,3)
        [0 2 1]

       histogram processes bad values.  It will set the bad-value flag of all output ndarrays if
       the flag is set for any of the input ndarrays.

   whistogram
         Signature: (in(n); float+ wt(n);float+[o] hist(m); double step; double min; int msize => m)

       Calculates a histogram from weighted data for given stepsize and minimum.

        $h = whistogram($data, $weights, $step, $min, $numbins);
        $hist = zeroes $numbins;  # Put histogram in existing ndarray.
        whistogram($data, $weights, $hist, $step, $min, $numbins);

       The histogram will contain $numbins bins starting from $min, each $step wide. The value in
       each bin is the sum of the values in $weights that correspond to values in $data that lie
       within the bin limits.

       Data below the lower limit is put in the first bin, and data above the upper limit is put
       in the last bin.

       The output is reset in a different broadcastloop so that you can take a histogram of
       "$a(10,12)" into "$b(15)" and get the result you want.

        pdl> p whistogram(pdl(1,1,2), pdl(0.1,0.1,0.5), 1, 0, 4)
        [0 0.2 0.5 0]

       whistogram processes bad values.  It will set the bad-value flag of all output ndarrays if
       the flag is set for any of the input ndarrays.

   histogram2d
         Signature: (ina(n); inb(n); int+[o] hist(ma,mb); double stepa; double mina; int masize => ma;
                            double stepb; double minb; int mbsize => mb;)

       Calculates a 2d histogram.

        $h = histogram2d($datax, $datay, $stepx, $minx,
              $nbinx, $stepy, $miny, $nbiny);
        $hist = zeroes $nbinx, $nbiny;  # Put histogram in existing ndarray.
        histogram2d($datax, $datay, $hist, $stepx, $minx,
              $nbinx, $stepy, $miny, $nbiny);

       The histogram will contain $nbinx x $nbiny bins, with the lower limits of the first one at
       "($minx, $miny)", and with bin size "($stepx, $stepy)".  The value in each bin is the
       number of values in $datax and $datay that lie within the bin limits.

       Data below the lower limit is put in the first bin, and data above the upper limit is put
       in the last bin.

        pdl> p histogram2d(pdl(1,1,1,2,2),pdl(2,1,1,1,1),1,0,3,1,0,3)
        [
         [0 0 0]
         [0 2 2]
         [0 1 0]
        ]

       histogram2d processes bad values.  It will set the bad-value flag of all output ndarrays
       if the flag is set for any of the input ndarrays.

   whistogram2d
         Signature: (ina(n); inb(n); float+ wt(n);float+[o] hist(ma,mb); double stepa; double mina; int masize => ma;
                            double stepb; double minb; int mbsize => mb;)

       Calculates a 2d histogram from weighted data.

        $h = whistogram2d($datax, $datay, $weights,
              $stepx, $minx, $nbinx, $stepy, $miny, $nbiny);
        $hist = zeroes $nbinx, $nbiny;  # Put histogram in existing ndarray.
        whistogram2d($datax, $datay, $weights, $hist,
              $stepx, $minx, $nbinx, $stepy, $miny, $nbiny);

       The histogram will contain $nbinx x $nbiny bins, with the lower limits of the first one at
       "($minx, $miny)", and with bin size "($stepx, $stepy)".  The value in each bin is the sum
       of the values in $weights that correspond to values in $datax and $datay that lie within
       the bin limits.

       Data below the lower limit is put in the first bin, and data above the upper limit is put
       in the last bin.

        pdl> p whistogram2d(pdl(1,1,1,2,2),pdl(2,1,1,1,1),pdl(0.1,0.2,0.3,0.4,0.5),1,0,3,1,0,3)
        [
         [  0   0   0]
         [  0 0.5 0.9]
         [  0 0.1   0]
        ]

       whistogram2d processes bad values.  It will set the bad-value flag of all output ndarrays
       if the flag is set for any of the input ndarrays.

   fibonacci
         Signature: (i(n); indx [o]x(n))

       Constructor - a vector with Fibonacci's sequence

       fibonacci does not process bad values.  It will set the bad-value flag of all output
       ndarrays if the flag is set for any of the input ndarrays.

   append
         Signature: (a(n); b(m); [o] c(mn))

       append two ndarrays by concatenating along their first dimensions

        $x = ones(2,4,7);
        $y = sequence 5;
        $c = $x->append($y);  # size of $c is now (7,4,7) (a jumbo-ndarray ;)

       "append" appends two ndarrays along their first dimensions. The rest of the dimensions
       must be compatible in the broadcasting sense. The resulting size of the first dimension is
       the sum of the sizes of the first dimensions of the two argument ndarrays - i.e. "n + m".

       Similar functions include "glue" (below), which can append more than two ndarrays along an
       arbitrary dimension, and cat, which can append more than two ndarrays that all have the
       same sized dimensions.

       append does not process bad values.  It will set the bad-value flag of all output ndarrays
       if the flag is set for any of the input ndarrays.

   glue
         $c = $x->glue(<dim>,$y,...)

       Glue two or more PDLs together along an arbitrary dimension (N-D "append").

       Sticks $x, $y, and all following arguments together along the specified dimension.  All
       other dimensions must be compatible in the broadcasting sense.

       Glue is permissive, in the sense that every PDL is treated as having an infinite number of
       trivial dimensions of order 1 -- so "$x->glue(3,$y)" works, even if $x and $y are only one
       dimensional.

       If one of the PDLs has no elements, it is ignored.  Likewise, if one of them is actually
       the undefined value, it is treated as if it had no elements.

       If the first parameter is a defined perl scalar rather than a pdl, then it is taken as a
       dimension along which to glue everything else, so you can say "$cube =
       PDL::glue(3,@image_list);" if you like.

       "glue" is implemented in pdl, using a combination of xchg and "append".  It should
       probably be updated (one day) to a pure PP function.

       Similar functions include "append" (above), which appends only two ndarrays along their
       first dimension, and cat, which can append more than two ndarrays that all have the same
       sized dimensions.

   cmpvec
         Signature: (a(n); b(n); sbyte [o]c())

       Compare two vectors lexicographically.

       Returns -1 if a is less, 1 if greater, 0 if equal.

       The output is bad if any input values up to the point of inequality are bad - any after
       are ignored.

   eqvec
         Signature: (a(n); b(n); sbyte [o]c())

       Compare two vectors, returning 1 if equal, 0 if not equal.

       The output is bad if any input values are bad.

   enumvec
         Signature: (v(M,N); indx [o]k(N))

       Enumerate a list of vectors with locally unique keys.

       Given a sorted list of vectors $v, generate a vector $k containing locally unique keys for
       the elements of $v (where an "element" is a vector of length $M occurring in $v).

       Note that the keys returned in $k are only unique over a run of a single vector in $v, so
       that each unique vector in $v has at least one 0 (zero) index in $k associated with it.
       If you need global keys, see enumvecg().

       Contributed by Bryan Jurish <moocow@cpan.org>.

       enumvec does not process bad values.  It will set the bad-value flag of all output
       ndarrays if the flag is set for any of the input ndarrays.

   enumvecg
         Signature: (v(M,N); indx [o]k(N))

       Enumerate a list of vectors with globally unique keys.

       Given a sorted list of vectors $v, generate a vector $k containing globally unique keys
       for the elements of $v (where an "element" is a vector of length $M occurring in $v).
       Basically does the same thing as:

        $k = $v->vsearchvec($v->uniqvec);

       ... but somewhat more efficiently.

       Contributed by Bryan Jurish <moocow@cpan.org>.

       enumvecg does not process bad values.  It will set the bad-value flag of all output
       ndarrays if the flag is set for any of the input ndarrays.

   vsearchvec
         Signature: (find(M); which(M,N); indx [o]found())

       Routine for searching N-dimensional values - akin to vsearch() for vectors.

        $found   = vsearchvec($find, $which);
        $nearest = $which->dice_axis(1,$found);

       Returns for each row-vector in $find the index along dimension N of the least row vector
       of $which greater or equal to it.  $which should be sorted in increasing order.  If the
       value of $find is larger than any member of $which, the index to the last element of
       $which is returned.

       See also: "vsearch".  Contributed by Bryan Jurish <moocow@cpan.org>.

       vsearchvec does not process bad values.  It will set the bad-value flag of all output
       ndarrays if the flag is set for any of the input ndarrays.

   unionvec
         Signature: (a(M,NA); b(M,NB); [o]c(M,NC); indx [o]nc())

       Union of two vector-valued PDLs.

       Input PDLs $a() and $b() MUST be sorted in lexicographic order.  On return, $nc() holds
       the actual number of vector-values in the union.

       In scalar context, slices $c() to the actual number of elements in the union and returns
       the sliced PDL.

       Contributed by Bryan Jurish <moocow@cpan.org>.

       unionvec does not process bad values.  It will set the bad-value flag of all output
       ndarrays if the flag is set for any of the input ndarrays.

   intersectvec
         Signature: (a(M,NA); b(M,NB); [o]c(M,NC); indx [o]nc())

       Intersection of two vector-valued PDLs.  Input PDLs $a() and $b() MUST be sorted in
       lexicographic order.  On return, $nc() holds the actual number of vector-values in the
       intersection.

       In scalar context, slices $c() to the actual number of elements in the intersection and
       returns the sliced PDL.

       Contributed by Bryan Jurish <moocow@cpan.org>.

       intersectvec does not process bad values.  It will set the bad-value flag of all output
       ndarrays if the flag is set for any of the input ndarrays.

   setdiffvec
         Signature: (a(M,NA); b(M,NB); [o]c(M,NC); indx [o]nc())

       Set-difference ($a() \ $b()) of two vector-valued PDLs.

       Input PDLs $a() and $b() MUST be sorted in lexicographic order.  On return, $nc() holds
       the actual number of vector-values in the computed vector set.

       In scalar context, slices $c() to the actual number of elements in the output vector set
       and returns the sliced PDL.

       Contributed by Bryan Jurish <moocow@cpan.org>.

       setdiffvec does not process bad values.  It will set the bad-value flag of all output
       ndarrays if the flag is set for any of the input ndarrays.

   union_sorted
         Signature: (a(NA); b(NB); [o]c(NC); indx [o]nc())

       Union of two flat sorted unique-valued PDLs.  Input PDLs $a() and $b() MUST be sorted in
       lexicographic order and contain no duplicates.  On return, $nc() holds the actual number
       of values in the union.

       In scalar context, reshapes $c() to the actual number of elements in the union and returns
       it.

       Contributed by Bryan Jurish <moocow@cpan.org>.

       union_sorted does not process bad values.  It will set the bad-value flag of all output
       ndarrays if the flag is set for any of the input ndarrays.

   intersect_sorted
         Signature: (a(NA); b(NB); [o]c(NC); indx [o]nc())

       Intersection of two flat sorted unique-valued PDLs.  Input PDLs $a() and $b() MUST be
       sorted in lexicographic order and contain no duplicates.  On return, $nc() holds the
       actual number of values in the intersection.

       In scalar context, reshapes $c() to the actual number of elements in the intersection and
       returns it.

       Contributed by Bryan Jurish <moocow@cpan.org>.

       intersect_sorted does not process bad values.  It will set the bad-value flag of all
       output ndarrays if the flag is set for any of the input ndarrays.

   setdiff_sorted
         Signature: (a(NA); b(NB); [o]c(NC); indx [o]nc())

       Set-difference ($a() \ $b()) of two flat sorted unique-valued PDLs.

       Input PDLs $a() and $b() MUST be sorted in lexicographic order and contain no duplicate
       values.  On return, $nc() holds the actual number of values in the computed vector set.

       In scalar context, reshapes $c() to the actual number of elements in the difference set
       and returns it.

       Contributed by Bryan Jurish <moocow@cpan.org>.

       setdiff_sorted does not process bad values.  It will set the bad-value flag of all output
       ndarrays if the flag is set for any of the input ndarrays.

   srand
         Signature: (a())

       Seed random-number generator with a 64-bit int. Will generate seed data for a number of
       threads equal to the return-value of "online_cpus" in PDL::Core.

        srand(); # uses current time
        srand(5); # fixed number e.g. for testing

       srand does not process bad values.  It will set the bad-value flag of all output ndarrays
       if the flag is set for any of the input ndarrays.

   random
         Signature: (a())

       Constructor which returns ndarray of random numbers

        $x = random([type], $nx, $ny, $nz,...);
        $x = random $y;

       etc (see zeroes).

       This is the uniform distribution between 0 and 1 (assumedly excluding 1 itself). The
       arguments are the same as "zeroes" (q.v.) - i.e. one can specify dimensions, types or give
       a template.

       You can use the PDL function "srand" to seed the random generator.  If it has not been
       called yet, it will be with the current time.

       random does not process bad values.  It will set the bad-value flag of all output ndarrays
       if the flag is set for any of the input ndarrays.

   randsym
         Signature: (a())

       Constructor which returns ndarray of random numbers

        $x = randsym([type], $nx, $ny, $nz,...);
        $x = randsym $y;

       etc (see zeroes).

       This is the uniform distribution between 0 and 1 (excluding both 0 and 1, cf "random").
       The arguments are the same as "zeroes" (q.v.) - i.e. one can specify dimensions, types or
       give a template.

       You can use the PDL function "srand" to seed the random generator.  If it has not been
       called yet, it will be with the current time.

       randsym does not process bad values.  It will set the bad-value flag of all output
       ndarrays if the flag is set for any of the input ndarrays.

   grandom
       Constructor which returns ndarray of Gaussian random numbers

        $x = grandom([type], $nx, $ny, $nz,...);
        $x = grandom $y;

       etc (see zeroes).

       This is generated using the math library routine "ndtri".

       Mean = 0, Stddev = 1

       You can use the PDL function "srand" to seed the random generator.  If it has not been
       called yet, it will be with the current time.

   vsearch
         Signature: ( vals(); xs(n); [o] indx(); [\%options] )

       Efficiently search for values in a sorted ndarray, returning indices.

         $idx = vsearch( $vals, $x, [\%options] );
         vsearch( $vals, $x, $idx, [\%options ] );

       vsearch performs a binary search in the ordered ndarray $x, for the values from $vals
       ndarray, returning indices into $x.  What is a "match", and the meaning of the returned
       indices, are determined by the options.

       The "mode" option indicates which method of searching to use, and may be one of:

       "sample"
           invoke vsearch_sample, returning indices appropriate for sampling within a
           distribution.

       "insert_leftmost"
           invoke vsearch_insert_leftmost, returning the left-most possible insertion point which
           still leaves the ndarray sorted.

       "insert_rightmost"
           invoke vsearch_insert_rightmost, returning the right-most possible insertion point
           which still leaves the ndarray sorted.

       "match"
           invoke vsearch_match, returning the index of a matching element, else -(insertion
           point + 1)

       "bin_inclusive"
           invoke vsearch_bin_inclusive, returning an index appropriate for binning on a grid
           where the left bin edges are inclusive of the bin. See below for further explanation
           of the bin.

       "bin_exclusive"
           invoke vsearch_bin_exclusive, returning an index appropriate for binning on a grid
           where the left bin edges are exclusive of the bin. See below for further explanation
           of the bin.

       The default value of "mode" is "sample".

         use PDL;

         my @modes = qw( sample insert_leftmost insert_rightmost match
                         bin_inclusive bin_exclusive );

         # Generate a sequence of 3 zeros, 3 ones, ..., 3 fours.
         my $x = zeroes(3,5)->yvals->flat;

         for my $mode ( @modes ) {
           # if the value is in $x
           my $contained = 2;
           my $idx_contained = vsearch( $contained, $x, { mode => $mode } );
           my $x_contained = $x->copy;
           $x_contained->slice( $idx_contained ) .= 9;

           # if the value is not in $x
           my $not_contained = 1.5;
           my $idx_not_contained = vsearch( $not_contained, $x, { mode => $mode } );
           my $x_not_contained = $x->copy;
           $x_not_contained->slice( $idx_not_contained ) .= 9;

           print sprintf("%-23s%30s\n", '$x', $x);
           print sprintf("%-23s%30s\n",   "$mode ($contained)", $x_contained);
           print sprintf("%-23s%30s\n\n", "$mode ($not_contained)", $x_not_contained);
         }

         # $x                     [0 0 0 1 1 1 2 2 2 3 3 3 4 4 4]
         # sample (2)             [0 0 0 1 1 1 9 2 2 3 3 3 4 4 4]
         # sample (1.5)           [0 0 0 1 1 1 9 2 2 3 3 3 4 4 4]
         #
         # $x                     [0 0 0 1 1 1 2 2 2 3 3 3 4 4 4]
         # insert_leftmost (2)    [0 0 0 1 1 1 9 2 2 3 3 3 4 4 4]
         # insert_leftmost (1.5)  [0 0 0 1 1 1 9 2 2 3 3 3 4 4 4]
         #
         # $x                     [0 0 0 1 1 1 2 2 2 3 3 3 4 4 4]
         # insert_rightmost (2)   [0 0 0 1 1 1 2 2 2 9 3 3 4 4 4]
         # insert_rightmost (1.5) [0 0 0 1 1 1 9 2 2 3 3 3 4 4 4]
         #
         # $x                     [0 0 0 1 1 1 2 2 2 3 3 3 4 4 4]
         # match (2)              [0 0 0 1 1 1 2 9 2 3 3 3 4 4 4]
         # match (1.5)            [0 0 0 1 1 1 2 2 9 3 3 3 4 4 4]
         #
         # $x                     [0 0 0 1 1 1 2 2 2 3 3 3 4 4 4]
         # bin_inclusive (2)      [0 0 0 1 1 1 2 2 9 3 3 3 4 4 4]
         # bin_inclusive (1.5)    [0 0 0 1 1 9 2 2 2 3 3 3 4 4 4]
         #
         # $x                     [0 0 0 1 1 1 2 2 2 3 3 3 4 4 4]
         # bin_exclusive (2)      [0 0 0 1 1 9 2 2 2 3 3 3 4 4 4]
         # bin_exclusive (1.5)    [0 0 0 1 1 9 2 2 2 3 3 3 4 4 4]

       Also see vsearch_sample, vsearch_insert_leftmost, vsearch_insert_rightmost, vsearch_match,
       vsearch_bin_inclusive, and vsearch_bin_exclusive

   vsearch_sample
         Signature: (vals(); x(n); indx [o]idx())

       Search for values in a sorted array, return index appropriate for sampling from a
       distribution

         $idx = vsearch_sample($vals, $x);

       $x must be sorted, but may be in decreasing or increasing order.

       vsearch_sample returns an index I for each value V of $vals appropriate for sampling $vals

       I has the following properties:

       •   if $x is sorted in increasing order

                     V <= x[0]  : I = 0
             x[0]  < V <= x[-1] : I s.t. x[I-1] < V <= x[I]
             x[-1] < V          : I = $x->nelem -1

       •   if $x is sorted in decreasing order

                      V > x[0]  : I = 0
             x[0]  >= V > x[-1] : I s.t. x[I] >= V > x[I+1]
             x[-1] >= V         : I = $x->nelem - 1

       If all elements of $x are equal, I = $x->nelem - 1.

       If $x contains duplicated elements, I is the index of the leftmost (by position in array)
       duplicate if V matches.

       This function is useful e.g. when you have a list of probabilities for events and want to
       generate indices to events:

        $x = pdl(.01,.86,.93,1); # Barnsley IFS probabilities cumulatively
        $y = random 20;
        $c = vsearch_sample($y, $x); # Now, $c will have the appropriate distr.

       It is possible to use the cumusumover function to obtain cumulative probabilities from
       absolute probabilities.

       needs major (?) work to handles bad values

   vsearch_insert_leftmost
         Signature: (vals(); x(n); indx [o]idx())

       Determine the insertion point for values in a sorted array, inserting before duplicates.

         $idx = vsearch_insert_leftmost($vals, $x);

       $x must be sorted, but may be in decreasing or increasing order.

       vsearch_insert_leftmost returns an index I for each value V of $vals equal to the leftmost
       position (by index in array) within $x that V may be inserted and still maintain the order
       in $x.

       Insertion at index I involves shifting elements I and higher of $x to the right by one and
       setting the now empty element at index I to V.

       I has the following properties:

       •   if $x is sorted in increasing order

                     V <= x[0]  : I = 0
             x[0]  < V <= x[-1] : I s.t. x[I-1] < V <= x[I]
             x[-1] < V          : I = $x->nelem

       •   if $x is sorted in decreasing order

                      V >  x[0]  : I = -1
             x[0]  >= V >= x[-1] : I s.t. x[I] >= V > x[I+1]
             x[-1] >= V          : I = $x->nelem -1

       If all elements of $x are equal,

           i = 0

       If $x contains duplicated elements, I is the index of the leftmost (by index in array)
       duplicate if V matches.

       needs major (?) work to handles bad values

   vsearch_insert_rightmost
         Signature: (vals(); x(n); indx [o]idx())

       Determine the insertion point for values in a sorted array, inserting after duplicates.

         $idx = vsearch_insert_rightmost($vals, $x);

       $x must be sorted, but may be in decreasing or increasing order.

       vsearch_insert_rightmost returns an index I for each value V of $vals equal to the
       rightmost position (by index in array) within $x that V may be inserted and still maintain
       the order in $x.

       Insertion at index I involves shifting elements I and higher of $x to the right by one and
       setting the now empty element at index I to V.

       I has the following properties:

       •   if $x is sorted in increasing order

                      V < x[0]  : I = 0
             x[0]  <= V < x[-1] : I s.t. x[I-1] <= V < x[I]
             x[-1] <= V         : I = $x->nelem

       •   if $x is sorted in decreasing order

                     V >= x[0]  : I = -1
             x[0]  > V >= x[-1] : I s.t. x[I] >= V > x[I+1]
             x[-1] > V          : I = $x->nelem -1

       If all elements of $x are equal,

           i = $x->nelem - 1

       If $x contains duplicated elements, I is the index of the leftmost (by index in array)
       duplicate if V matches.

       needs major (?) work to handles bad values

   vsearch_match
         Signature: (vals(); x(n); indx [o]idx())

       Match values against a sorted array.

         $idx = vsearch_match($vals, $x);

       $x must be sorted, but may be in decreasing or increasing order.

       vsearch_match returns an index I for each value V of $vals.  If V matches an element in
       $x, I is the index of that element, otherwise it is -( insertion_point + 1 ), where
       insertion_point is an index in $x where V may be inserted while maintaining the order in
       $x.  If $x has duplicated values, I may refer to any of them.

       needs major (?) work to handles bad values

   vsearch_bin_inclusive
         Signature: (vals(); x(n); indx [o]idx())

       Determine the index for values in a sorted array of bins, lower bound inclusive.

         $idx = vsearch_bin_inclusive($vals, $x);

       $x must be sorted, but may be in decreasing or increasing order.

       $x represents the edges of contiguous bins, with the first and last elements representing
       the outer edges of the outer bins, and the inner elements the shared bin edges.

       The lower bound of a bin is inclusive to the bin, its outer bound is exclusive to it.
       vsearch_bin_inclusive returns an index I for each value V of $vals

       I has the following properties:

       •   if $x is sorted in increasing order

                      V < x[0]  : I = -1
             x[0]  <= V < x[-1] : I s.t. x[I] <= V < x[I+1]
             x[-1] <= V         : I = $x->nelem - 1

       •   if $x is sorted in decreasing order

                      V >= x[0]  : I = 0
             x[0]  >  V >= x[-1] : I s.t. x[I+1] > V >= x[I]
             x[-1] >  V          : I = $x->nelem

       If all elements of $x are equal,

           i = $x->nelem - 1

       If $x contains duplicated elements, I is the index of the righmost (by index in array)
       duplicate if V matches.

       needs major (?) work to handles bad values

   vsearch_bin_exclusive
         Signature: (vals(); x(n); indx [o]idx())

       Determine the index for values in a sorted array of bins, lower bound exclusive.

         $idx = vsearch_bin_exclusive($vals, $x);

       $x must be sorted, but may be in decreasing or increasing order.

       $x represents the edges of contiguous bins, with the first and last elements representing
       the outer edges of the outer bins, and the inner elements the shared bin edges.

       The lower bound of a bin is exclusive to the bin, its upper bound is inclusive to it.
       vsearch_bin_exclusive returns an index I for each value V of $vals.

       I has the following properties:

       •   if $x is sorted in increasing order

                      V <= x[0]  : I = -1
             x[0]  <  V <= x[-1] : I s.t. x[I] < V <= x[I+1]
             x[-1] <  V          : I = $x->nelem - 1

       •   if $x is sorted in decreasing order

                      V >  x[0]  : I = 0
             x[0]  >= V >  x[-1] : I s.t. x[I-1] >= V > x[I]
             x[-1] >= V          : I = $x->nelem

       If all elements of $x are equal,

           i = $x->nelem - 1

       If $x contains duplicated elements, I is the index of the righmost (by index in array)
       duplicate if V matches.

       needs major (?) work to handles bad values

   interpolate
         Signature: (real xi(); real x(n); y(n); [o] yi(); int [o] err())

       routine for 1D linear interpolation

        ( $yi, $err ) = interpolate($xi, $x, $y)

       Given a set of points "($x,$y)", use linear interpolation to find the values $yi at a set
       of points $xi.

       "interpolate" uses a binary search to find the suspects, er..., interpolation indices and
       therefore abscissas (ie $x) have to be strictly ordered (increasing or decreasing).  For
       interpolation at lots of closely spaced abscissas an approach that uses the last index
       found as a start for the next search can be faster (compare Numerical Recipes "hunt"
       routine). Feel free to implement that on top of the binary search if you like. For out of
       bounds values it just does a linear extrapolation and sets the corresponding element of
       $err to 1, which is otherwise 0.

       See also "interpol", which uses the same routine, differing only in the handling of
       extrapolation - an error message is printed rather than returning an error ndarray.

       Note that "interpolate" can use complex values for $y and $yi but $x and $xi must be real.

       needs major (?) work to handles bad values

   interpol
        Signature: (xi(); x(n); y(n); [o] yi())

       routine for 1D linear interpolation

        $yi = interpol($xi, $x, $y)

       "interpol" uses the same search method as "interpolate", hence $x must be strictly ordered
       (either increasing or decreasing).  The difference occurs in the handling of out-of-bounds
       values; here an error message is printed.

   interpND
       Interpolate values from an N-D ndarray, with switchable method

         $source = 10*xvals(10,10) + yvals(10,10);
         $index = pdl([[2.2,3.5],[4.1,5.0]],[[6.0,7.4],[8,9]]);
         print $source->interpND( $index );

       InterpND acts like indexND, collapsing $index by lookup into $source; but it does
       interpolation rather than direct sampling.  The interpolation method and boundary
       condition are switchable via an options hash.

       By default, linear or sample interpolation is used, with constant value outside the
       boundaries of the source pdl.  No dataflow occurs, because in general the output is
       computed rather than indexed.

       All the interpolation methods treat the pixels as value-centered, so the "sample" method
       will return "$a->(0)" for coordinate values on the set [-0.5,0.5), and all methods will
       return "$a->(1)" for a coordinate value of exactly 1.

       Recognized options:

       method
          Values can be:

          •  0, s, sample, Sample (default for integer source types)

             The nearest value is taken. Pixels are regarded as centered on their respective
             integer coordinates (no offset from the linear case).

          •  1, l, linear, Linear (default for floating point source types)

             The values are N-linearly interpolated from an N-dimensional cube of size 2.

          •  3, c, cube, cubic, Cubic

             The values are interpolated using a local cubic fit to the data.  The fit is
             constrained to match the original data and its derivative at the data points.  The
             second derivative of the fit is not continuous at the data points.  Multidimensional
             datasets are interpolated by the successive-collapse method.

             (Note that the constraint on the first derivative causes a small amount of ringing
             around sudden features such as step functions).

          •  f, fft, fourier, Fourier

             The source is Fourier transformed, and the interpolated values are explicitly
             calculated from the coefficients.  The boundary condition option is ignored --
             periodic boundaries are imposed.

             If you pass in the option "fft", and it is a list (ARRAY) ref, then it is a stash
             for the magnitude and phase of the source FFT.  If the list has two elements then
             they are taken as already computed; otherwise they are calculated and put in the
             stash.

       b, bound, boundary, Boundary
          This option is passed unmodified into indexND, which is used as the indexing engine for
          the interpolation.  Some current allowed values are 'extend', 'periodic', 'truncate',
          and 'mirror' (default is 'truncate').

       bad
          contains the fill value used for 'truncate' boundary.  (default 0)

       fft
          An array ref whose associated list is used to stash the FFT of the source data, for the
          FFT method.

   one2nd
       Converts a one dimensional index ndarray to a set of ND coordinates

        @coords=one2nd($x, $indices)

       returns an array of ndarrays containing the ND indexes corresponding to the one
       dimensional list indices. The indices are assumed to correspond to array $x clumped using
       "clump(-1)". This routine is used in the old vector form of "whichND", but is useful on
       its own occasionally.

       Returned ndarrays have the indx datatype.  $indices can have values larger than
       "$x->nelem" but negative values in $indices will not give the answer you expect.

        pdl> $x=pdl [[[1,2],[-1,1]], [[0,-3],[3,2]]]; $c=$x->clump(-1)
        pdl> $maxind=maximum_ind($c); p $maxind;
        6
        pdl> print one2nd($x, maximum_ind($c))
        0 1 1
        pdl> p $x->at(0,1,1)
        3

   which
         Signature: (mask(n); indx [o] inds(n); indx [o]lastout())

       Returns indices of non-zero values from a 1-D PDL

        $i = which($mask);

       returns a pdl with indices for all those elements that are nonzero in the mask. Note that
       the returned indices will be 1D. If you feed in a multidimensional mask, it will be
       flattened before the indices are calculated.  See also "whichND" for multidimensional
       masks.

       If you want to index into the original mask or a similar ndarray with output from "which",
       remember to flatten it before calling index:

         $data = random 5, 5;
         $idx = which $data > 0.5; # $idx is now 1D
         $bigsum = $data->flat->index($idx)->sum;  # flatten before indexing

       Compare also "where" for similar functionality.

       SEE ALSO:

       "which_both" returns separately the indices of both nonzero and zero values in the mask.

       "where_both" returns separately slices of both nonzero and zero values in the mask.

       "where" returns associated values from a data PDL, rather than indices into the mask PDL.

       "whichND" returns N-D indices into a multidimensional PDL.

        pdl> $x = sequence(10); p $x
        [0 1 2 3 4 5 6 7 8 9]
        pdl> $indx = which($x>6); p $indx
        [7 8 9]

       which processes bad values.  It will set the bad-value flag of all output ndarrays if the
       flag is set for any of the input ndarrays.

   which_both
         Signature: (mask(n); indx [o] inds(n); indx [o]notinds(n); indx [o]lastout(); indx [o]lastoutn())

       Returns indices of nonzero and zero values in a mask PDL

        ($i, $c_i) = which_both($mask);

       This works just as "which", but the complement of $i will be in $c_i.

        pdl> p $x = sequence(10)
        [0 1 2 3 4 5 6 7 8 9]
        pdl> ($big, $small) = which_both($x >= 5); p "$big\n$small"
        [5 6 7 8 9]
        [0 1 2 3 4]

       which_both processes bad values.  It will set the bad-value flag of all output ndarrays if
       the flag is set for any of the input ndarrays.

   where
       Use a mask to select values from one or more data PDLs

       "where" accepts one or more data ndarrays and a mask ndarray.  It returns a list of output
       ndarrays, corresponding to the input data ndarrays.  Each output ndarray is a
       1-dimensional list of values in its corresponding data ndarray. The values are drawn from
       locations where the mask is nonzero.

       The output PDLs are still connected to the original data PDLs, for the purpose of
       dataflow.

       "where" combines the functionality of "which" and index into a single operation.

       BUGS:

       While "where" works OK for most N-dimensional cases, it does not broadcast properly over
       (for example) the (N+1)th dimension in data that is compared to an N-dimensional mask.
       Use "whereND" for that.

        $i = $x->where($x+5 > 0); # $i contains those elements of $x
                                  # where mask ($x+5 > 0) is 1
        $i .= -5;  # Set those elements (of $x) to -5. Together, these
                   # commands clamp $x to a maximum of -5.

       It is also possible to use the same mask for several ndarrays with the same call:

        ($i,$j,$k) = where($x,$y,$z, $x+5>0);

       Note: $i is always 1-D, even if $x is >1-D.

       WARNING: The first argument (the values) and the second argument (the mask) currently have
       to have the exact same dimensions (or horrible things happen). You *cannot* broadcast over
       a smaller mask, for example.

   where_both
       Returns slices (non-zero in mask, zero) of an ndarray according to a mask

        ($match_vals, $non_match_vals) = where_both($pdl, $mask);

       This works like "which_both", but (flattened) data-flowing slices rather than index-sets
       are returned.

        pdl> p $x = sequence(10) + 2
        [2 3 4 5 6 7 8 9 10 11]
        pdl> ($big, $small) = where_both($x, $x > 5); p "$big\n$small"
        [6 7 8 9 10 11]
        [2 3 4 5]
        pdl> p $big += 2, $small -= 1
        [8 9 10 11 12 13] [1 2 3 4]
        pdl> p $x
        [1 2 3 4 8 9 10 11 12 13]

   whereND
       "where" with support for ND masks and broadcasting

       "whereND" accepts one or more data ndarrays and a mask ndarray.  It returns a list of
       output ndarrays, corresponding to the input data ndarrays.  The values are drawn from
       locations where the mask is nonzero.

       "whereND" differs from "where" in that the mask dimensionality is preserved which allows
       for proper broadcasting of the selection operation over higher dimensions.

       As with "where" the output PDLs are still connected to the original data PDLs, for the
       purpose of dataflow.

         $sdata = whereND $data, $mask
         ($s1, $s2, ..., $sn) = whereND $d1, $d2, ..., $dn, $mask

         where

           $data is M dimensional
           $mask is N < M dimensional
           dims($data) 1..N == dims($mask) 1..N
           with broadcasting over N+1 to M dimensions

         $data   = sequence(4,3,2);   # example data array
         $mask4  = (random(4)>0.5);   # example 1-D mask array, has $n4 true values
         $mask43 = (random(4,3)>0.5); # example 2-D mask array, has $n43 true values
         $sdat4  = whereND $data, $mask4;   # $sdat4 is a [$n4,3,2] pdl
         $sdat43 = whereND $data, $mask43;  # $sdat43 is a [$n43,2] pdl

       Just as with "where", you can use the returned value in an assignment. That means that
       both of these examples are valid:

         # Used to create a new slice stored in $sdat4:
         $sdat4 = $data->whereND($mask4);
         $sdat4 .= 0;
         # Used in lvalue context:
         $data->whereND($mask4) .= 0;

       SEE ALSO:

       "whichND" returns N-D indices into a multidimensional PDL, from a mask.

   whichND
       Return the coordinates of non-zero values in a mask.

       WhichND returns the N-dimensional coordinates of each nonzero value in a mask PDL with any
       number of dimensions.  The returned values arrive as an array-of-vectors suitable for use
       in indexND or range.

        $coords = whichND($mask);

       returns a PDL containing the coordinates of the elements that are non-zero in $mask,
       suitable for use in "indexND" in PDL::Slices. The 0th dimension contains the full
       coordinate listing of each point; the 1st dimension lists all the points.  For example, if
       $mask has rank 4 and 100 matching elements, then $coords has dimension 4x100.

       If no such elements exist, then whichND returns a structured empty PDL: an Nx0 PDL that
       contains no values (but matches, broadcasting-wise, with the vectors that would be
       produced if such elements existed).

       DEPRECATED BEHAVIOR IN LIST CONTEXT:

       whichND once delivered different values in list context than in scalar context, for
       historical reasons.  In list context, it returned the coordinates transposed, as a
       collection of 1-PDLs (one per dimension) in a list.  This usage is deprecated in PDL
       2.4.10, and will cause a warning to be issued every time it is encountered.  To avoid the
       warning, you can set the global variable "$PDL::whichND" to 's' to get scalar behavior in
       all contexts, or to 'l' to get list behavior in list context.

       In later versions of PDL, the deprecated behavior will disappear.  Deprecated list context
       whichND expressions can be replaced with:

           @list = $x->whichND->mv(0,-1)->dog;

       SEE ALSO:

       "which" finds coordinates of nonzero values in a 1-D mask.

       "where" extracts values from a data PDL that are associated with nonzero values in a mask
       PDL.

       "indexND" in PDL::Slices can be fed the coordinates to return the values.

        pdl> $s=sequence(10,10,3,4)
        pdl> ($x, $y, $z, $w)=whichND($s == 203); p $x, $y, $z, $w
        [3] [0] [2] [0]
        pdl> print $s->at(list(cat($x,$y,$z,$w)))
        203

   setops
       Implements simple set operations like union and intersection

          Usage: $set = setops($x, <OPERATOR>, $y);

       The operator can be "OR", "XOR" or "AND". This is then applied to $x viewed as a set and
       $y viewed as a set. Set theory says that a set may not have two or more identical
       elements, but setops takes care of this for you, so "$x=pdl(1,1,2)" is OK. The functioning
       is as follows:

       "OR"
           The resulting vector will contain the elements that are either in $x or in $y or both.
           This is the union in set operation terms

       "XOR"
           The resulting vector will contain the elements that are either in $x or $y, but not in
           both. This is

                Union($x, $y) - Intersection($x, $y)

           in set operation terms.

       "AND"
           The resulting vector will contain the intersection of $x and $y, so the elements that
           are in both $x and $y. Note that for convenience this operation is also aliased to
           "intersect".

       It should be emphasized that these routines are used when one or both of the sets $x, $y
       are hard to calculate or that you get from a separate subroutine.

       Finally IDL users might be familiar with Craig Markwardt's "cmset_op.pro" routine which
       has inspired this routine although it was written independently However the present
       routine has a few less options (but see the examples)

       You will very often use these functions on an index vector, so that is what we will show
       here. We will in fact something slightly silly. First we will find all squares that are
       also cubes below 10000.

       Create a sequence vector:

         pdl> $x = sequence(10000)

       Find all odd and even elements:

         pdl> ($even, $odd) = which_both( ($x % 2) == 0)

       Find all squares

         pdl> $squares= which(ceil(sqrt($x)) == floor(sqrt($x)))

       Find all cubes (being careful with roundoff error!)

         pdl> $cubes= which(ceil($x**(1.0/3.0)) == floor($x**(1.0/3.0)+1e-6))

       Then find all squares that are cubes:

         pdl> $both = setops($squares, 'AND', $cubes)

       And print these (assumes that "PDL::NiceSlice" is loaded!)

         pdl> p $x($both)
          [0 1 64 729 4096]

       Then find all numbers that are either cubes or squares, but not both:

         pdl> $cube_xor_square = setops($squares, 'XOR', $cubes)

         pdl> p $cube_xor_square->nelem()
          112

       So there are a total of 112 of these!

       Finally find all odd squares:

         pdl> $odd_squares = setops($squares, 'AND', $odd)

       Another common occurrence is to want to get all objects that are in $x and in the
       complement of $y. But it is almost always best to create the complement explicitly since
       the universe that both are taken from is not known. Thus use "which_both" if possible to
       keep track of complements.

       If this is impossible the best approach is to make a temporary:

       This creates an index vector the size of the universe of the sets and set all elements in
       $y to 0

         pdl> $tmp = ones($n_universe); $tmp($y) .= 0;

       This then finds the complement of $y

         pdl> $C_b = which($tmp == 1);

       and this does the final selection:

         pdl> $set = setops($x, 'AND', $C_b)

   intersect
       Calculate the intersection of two ndarrays

          Usage: $set = intersect($x, $y);

       This routine is merely a simple interface to "setops". See that for more information

       Find all numbers less that 100 that are of the form 2*y and 3*x

        pdl> $x=sequence(100)
        pdl> $factor2 = which( ($x % 2) == 0)
        pdl> $factor3 = which( ($x % 3) == 0)
        pdl> $ii=intersect($factor2, $factor3)
        pdl> p $x($ii)
        [0 6 12 18 24 30 36 42 48 54 60 66 72 78 84 90 96]

AUTHOR

       Copyright (C) Tuomas J. Lukka 1997 (lukka@husc.harvard.edu). Contributions by Christian
       Soeller (c.soeller@auckland.ac.nz), Karl Glazebrook (kgb@aaoepp.aao.gov.au), Craig
       DeForest (deforest@boulder.swri.edu) and Jarle Brinchmann (jarle@astro.up.pt) All rights
       reserved. There is no warranty. You are allowed to redistribute this software /
       documentation under certain conditions. For details, see the file COPYING in the PDL
       distribution. If this file is separated from the PDL distribution, the copyright notice
       should be included in the file.

       Updated for CPAN viewing compatibility by David Mertens.