A quantile is a value which divides a frequency distribution such that there is a given proportion of data values below the quantile. For example, the median of a dataset is the $0.5$ quantile because half the values are less than or equal to it.
g01apf uses a slightly modified version of an algorithm described in a paper by
Zhang and Wang (2007) to determine
$\epsilon $approximate quantiles of a large arbitrarysized data stream of real values, where
$\epsilon $ is a userdefined approximation factor. Let
$m$ denote the number of data elements processed so far then, given any quantile
$q\in \left[0.0,1.0\right]$, an
$\epsilon $approximate quantile is defined as an element in the data stream whose rank falls within
$\left[\left(q\epsilon \right)m,\left(q+\epsilon \right)m\right]$. In case of more than one
$\epsilon $approximate quantile being available, the one closest to
$qm$ is used.
Zhang Q and Wang W (2007) A fast algorithm for approximate quantiles in high speed data streams Proceedings of the 19th International Conference on Scientific and Statistical Database Management IEEE Computer Society 29

1:
$\mathbf{ind}$ – Integer
Input/Output

On initial entry: must be set to $0$.
On entry: indicates the action required in the current call to
g01apf.
 ${\mathbf{ind}}=0$
 Initialize the communication arrays and attempt to process the first nb values from the data stream. eps, rv and nb must be set and licomm must be at least $10$.
 ${\mathbf{ind}}=1$
 Attempt to process the next block of nb values from the data stream. The calling program must update rv and (if required) nb, and reenter g01apf with all other parameters unchanged.
 ${\mathbf{ind}}=2$
 Continue calculation following the reallocation of either or both of the communication arrays rcomm and icomm.
 ${\mathbf{ind}}=3$
 Calculate the nq $\epsilon $approximate quantiles specified in q. The calling program must set q and nq and reenter g01apf with all other parameters unchanged. This option can be chosen only when ${\mathbf{np}}\ge \u2308\mathrm{exp}\left(1.0\right)/{\mathbf{eps}}\u2309$.
On exit: indicates output from the call.
 ${\mathbf{ind}}=1$
 g01apf has processed np data points and expects to be called again with additional data.
 ${\mathbf{ind}}=2$
 Either one or more of the communication arrays rcomm and icomm is too small. The new minimum lengths of rcomm and icomm have been returned in ${\mathbf{icomm}}\left(1\right)$ and ${\mathbf{icomm}}\left(2\right)$ respectively. If the new minimum length is greater than the current length then the corresponding communication array needs to be reallocated, its contents preserved and g01apf called again with all other parameters unchanged.
If there is more data to be processed, it is recommended that
lrcomm and
licomm are made significantly bigger than the minimum to limit the number of reallocations.
 ${\mathbf{ind}}=3$
 g01apf has returned the requested $\epsilon $approximate quantiles in qv. These quantiles are based on np data points.
Constraint:
${\mathbf{ind}}=0$, $1$, $2$ or $3$.

2:
$\mathbf{rv}\left(*\right)$ – Real (Kind=nag_wp) array
Input
Note: the dimension of the array
rv
must be at least
${\mathbf{nb}}$ if
${\mathbf{ind}}=0$,
$1$ or
$2$.
On entry: if
${\mathbf{ind}}=0$,
$1$ or
$2$, the vector containing the current block of data, otherwise
rv is not referenced.

3:
$\mathbf{nb}$ – Integer
Input

On entry: if
${\mathbf{ind}}=0$,
$1$ or
$2$, the size of the current block of data. The size of blocks of data in array
rv can vary; therefore
nb can change between calls to
g01apf.
Constraint:
if ${\mathbf{ind}}=0$, $1$ or $2$, ${\mathbf{nb}}>0$.

4:
$\mathbf{eps}$ – Real (Kind=nag_wp)
Input

On entry: approximation factor $\epsilon $.
Constraint:
${\mathbf{eps}}>0.0\text{ and}{\mathbf{eps}}\le 1.0$.

5:
$\mathbf{np}$ – Integer
Output

On exit: $m$, the number of elements processed so far.

6:
$\mathbf{q}\left(*\right)$ – Real (Kind=nag_wp) array
Input
Note: the dimension of the array
q
must be at least
${\mathbf{nq}}$ if
${\mathbf{ind}}=3$.
On entry: if
${\mathbf{ind}}=3$, the quantiles to be calculated, otherwise
q is not referenced. Note that
${\mathbf{q}}\left(i\right)=0.0$, corresponds to the minimum value and
${\mathbf{q}}\left(i\right)=1.0$ to the maximum value.
Constraint:
if ${\mathbf{ind}}=3$,
$0.0\le {\mathbf{q}}\left(\mathit{i}\right)\le 1.0$, for $\mathit{i}=1,2,\dots ,{\mathbf{nq}}$.

7:
$\mathbf{qv}\left(*\right)$ – Real (Kind=nag_wp) array
Output
Note: the dimension of the array
qv
must be at least
${\mathbf{nq}}$ if
${\mathbf{ind}}=3$.
On exit: if ${\mathbf{ind}}=3$, ${\mathbf{qv}}\left(i\right)$ contains the $\epsilon $approximate quantiles specified by the value provided in ${\mathbf{q}}\left(i\right)$.

8:
$\mathbf{nq}$ – Integer
Input

On entry: if
${\mathbf{ind}}=3$, the number of quantiles requested, otherwise
nq is not referenced.
Constraint:
if ${\mathbf{ind}}=3$, ${\mathbf{nq}}>0$.

9:
$\mathbf{rcomm}\left({\mathbf{lrcomm}}\right)$ – Real (Kind=nag_wp) array
Communication Array

On entry: if
${\mathbf{ind}}=1$ or
$2$ then the first
$l$ elements of
rcomm as supplied to
g01apf must be identical to the first
$l$ elements of
rcomm returned from the last call to
g01apf, where
$l$ is the value of
lrcomm used in the last call. In other words, the contents of
rcomm must not be altered between calls to this routine. If
rcomm needs to be reallocated then its contents must be preserved. If
${\mathbf{ind}}=0$ then
rcomm need not be set.
On exit:
rcomm holds information required by subsequent calls to
g01apf.

10:
$\mathbf{lrcomm}$ – Integer
Input

On entry: the dimension of the array
rcomm as declared in the (sub)program from which
g01apf is called.
Constraints:
 if ${\mathbf{ind}}=0$, ${\mathbf{lrcomm}}\ge 1$;
 otherwise ${\mathbf{lrcomm}}\ge {\mathbf{icomm}}\left(1\right)$.

11:
$\mathbf{icomm}\left({\mathbf{licomm}}\right)$ – Integer array
Communication Array

On entry: if
${\mathbf{ind}}=1$ or
$2$ then the first
$l$ elements of
icomm as supplied to
g01apf must be identical to the first
$l$ elements of
icomm returned from the last call to
g01apf, where
$l$ is the value of
licomm used in the last call. In other words, the contents of
icomm must not be altered between calls to this routine. If
icomm needs to be reallocated then its contents must be preserved. If
${\mathbf{ind}}=0$ then
icomm need not be set.
On exit:
${\mathbf{icomm}}\left(1\right)$ holds the minimum required length for
rcomm and
${\mathbf{icomm}}\left(2\right)$ holds the minimum required length for
icomm. The remaining elements of
icomm are used for communication between subsequent calls to
g01apf.

12:
$\mathbf{licomm}$ – Integer
Input

On entry: the dimension of the array
icomm as declared in the (sub)program from which
g01apf is called.
Constraints:
 if ${\mathbf{ind}}=0$, ${\mathbf{licomm}}\ge 10$;
 otherwise ${\mathbf{licomm}}\ge {\mathbf{icomm}}\left(2\right)$.

13:
$\mathbf{ifail}$ – Integer
Input/Output

On entry:
ifail must be set to
$0$,
$1$ or
$1$. If you are unfamiliar with this argument you should refer to
Section 7 in the Introduction to the NAG Library CL Interface for details.
On exit:
${\mathbf{ifail}}={\mathbf{0}}$ unless the routine detects an error (see
Section 6).
As an outofcore routine
g01apf will only perform certain argument checks when a data checkpoint (including completion of data input) is signaled. As such it will usually be inappropriate to halt program execution when an error is detected since any errors may be subsequently resolved without losing any processing already carried out. Therefore setting
ifail to a value of
$1$ or
$1$ is recommended. If the output of error messages is undesirable, the value
$1$ is recommended.
When the value $\mathbf{1}$ or $\mathbf{1}$ is used it is essential to test the value of ifail on exit.
If on entry
${\mathbf{ifail}}=0$ or
$1$, explanatory error messages are output on the current error message unit (as defined by
x04aaf).
Not applicable.
Please consult the
X06 Chapter Introduction for information on how to control and interrogate the OpenMP environment used within this routine. Please also consult the
Users' Note for your implementation for any additional implementationspecific information.
It is not possible to determine in advance the final size of the communication arrays
rcomm and
icomm without knowing the size of the dataset. However, if a rough size (
$n$) is known, the speed of the computation can be increased if the sizes of the communication arrays are not smaller than
where