Sets up table to generate pseudorandom numbers from a general discrete distribution.
#include <imsls.h>
float
*imsls_f_discrete_table_setup (float
prf(),
float
del,
int nndx, int
*imin,
int
*nmass,
..., 0)
The type double function is imsls_d_discrete_table_setup.
float prf(int ix)
(Input)
User-supplied function to compute the probability associated
with each mass point of the distribution The argument to the function is
the point at which the probability function is to be evaluated. ix can range from
imin to the
value at which the cumulative probability is greater than or equal to 1.0 - del.
float del
(Input)
Maximum absolute error allowed in
computing the cumulative probability.
Probabilities smaller than
del are ignored; hence, del should be a small positive number. If del is too small, however, the return value, cumpr [nmass-1] must be exactly 1.0 since that value is compared to
1.0 - del.
int nndx
(Input)
The number of elements of cumpr available to be used as indexes.
nndx must be greater than or equal to 1. In general, the larger
nndx is, to within sixty or seventy percent of nmass, the more efficient the generation of random numbers using
imsls_f_random_general_discrete
will be.
int *imin
(Input/Output)
Pointer to a scalar containing the smallest value the random deviate can assume.
(Input/Output)
imin is not used if optional argument IMSLS_INDEX_ONLY is used. By default, prf is evaluated at imin. If this value is less than del, imin is incremented by 1 and again prf is evaluated at imin. This process is continued until prf(imin) ³
del. imin is output as this value and the return value cumpr [0] is output as prf(imin).
int *nmass
(Input/Output)
Pointer to a scalar containing the number of mass points in the distribution.
Input, if IMSLS_INDEX_ONLY is used; otherwise, output.
By default, nmass is the smallest integer such that
prf(imin + nmass - 1)
> 1.0 - del. nmass does include the points iminin + j for
which prf(iminin + j) <
del, for j = 0, 1, ¼,
iminout -
iminin, where
iminin denotes the
input value of imin and iminout denotes its
output value.
Array, cumpr, of length nmass + nndx containing in the first nmass positions, the cumulative probabilities and in some of the remaining positions, indexes to speed access to the probabilities. To release this space, use free.
#include <imsls.h>
void
imsls_f_discrete_table_setup (float
prf(),
float del, int nndx, int
*imin,
int
*nmass,
IMSLS_INDEX_ONLY,
IMSLS_RETURN_USER, float
cumpr[],
int lcumpr,
IMSLS_FCN_W_DATA,
float
prf(), void
*data,
0)
IMSLS_INDEX_ONLY
(Intput)
Fill only the index portion of the result, cumpr, using the
values in the first nmass positions. prf is not used and
may be a dummy function; also, imin is not
used. The optional argument IMSLS_RETURN_USER is
required if IMSLS_INDEX_ONLY is
used.
IMSLS_RETURN_USER, float cumpr[], int
lcumpr
(Input/Output)
cumpr is a user-allocated array of length nmass + nndx containing in the first nmass positions, the cumulative probabilities and in some of the
remaining positions, indexes to speed access to the probabilities. lcumpr is the
actual length of cumpr as specified in the calling function. Since, by default, the logical length of cumpr is determined in imsls_f_discrete_table_setup, lcumpr is used for error checking. If the option
IMSLS_INDEX_ONLY
is used, then only the index
portion of cumpr
are filled.
IMSLS_FCN_W_DATA, float prf(int ix), void *data,
(Input)
User-supplied function to compute the probability associated with
each mass point of the distribution, which also accepts a pointer to data that
is supplied by the user. data is a pointer to
the data to be passed to the user-supplied function. See the Introduction, Passing Data
to User-Supplied Functions at the beginning of this manual for more
details.
Routine imsls_f_discrete_table_setup sets up a table that routine imsls_f_random_general_discrete uses to generate pseudorandom deviates from a discrete distribution. The distribution can be specified either by its probability function prf or by a vector of values of the cumulative probability function. Note that prf is not the cumulative probability distribution function. If the cumulative probabilities are already available in cumpr, the only reason to call imsls_f_discrete_table_setup is to form an index vector in the upper portion of cumpr so as to speed up the generation of random deviates by the routine imsls_f_random_general_discrete.
In this example, imsls_f_discrete_table_setup is used to set up a table to generate pseudorandom variates from the discrete distribution:
Pr(X = 1) = .05
Pr(X = 2) = .45
Pr(X = 3) = .31
Pr(X = 4) = .04
Pr(X = 5) = .15
In this simple example, we input the cumulative probabilities directly in cumpr and request 3 indexes to be computed (nndx = 4). Since the number of mass points is so small, the indexes would not have much effect on the speed of the generation of the random variates.
#include <stdio.h>
#include <imsls.h>
float prf(int ix);
void main()
{
int i, lcumpr = 9, ir[5];
int nndx = 4, imin = 1, nmass = 5, nr = 5;
float cumpr[9], del = 0.00001, *p_cumpr = NULL;
i = 0;
cumpr[i++] = .05;
cumpr[i++] = .5;
cumpr[i++] = .81;
cumpr[i++] = .85;
cumpr[i++] = 1.0;
imsls_f_discrete_table_setup (prf, del,
nndx, &imin, &nmass,
IMSLS_INDEX_ONLY,
IMSLS_RETURN_USER, cumpr, lcumpr,
0);
imsls_f_write_matrix("Cumulative probabilities and indexes",
1, lcumpr, cumpr, 0);
}
float prf(int ix)
{
return 0.;
}
Cumulative probabilities and indexes
1 2 3 4 5 6
0.05 0.50 0.81 0.85 1.00 3.00
7 8 9
1.00 2.00 5.00
This example, imsls_f_random_general_discrete is used to set up a table to generate binomial variates with parameters 20 and 0.5. The routine imsls_f_binomial_probabililty (Chapter 11, Probability Distribution Functions and Inverses;) is used to compute the probabilities.
#include <stdio.h>
#include <imsls.h>
float prf(int ix);
void main()
{
int lcumpr = 33;
int nndx = 12, imin = 0, nmass = 21, nr = 5;
float del = 0.00001, *cumpr;
int *ir = NULL;
cumpr = imsls_f_discrete_table_setup (prf, del, nndx, &imin, &nmass, 0);
printf("The smallest point with positive probability using \n");
printf("the given del is %d and all points after \n", imin);
printf("point number %d (counting from the input value\n", nmass);
printf("of IMIN) have zero probability.\n");
imsls_f_write_matrix("Cumulative probabilities and indexes",
nmass+nndx, 1, cumpr,
IMSLS_WRITE_FORMAT, "%11.7f", 0);
}
float prf(int ix)
{
int n = 20;
float p = .5;
return imsls_f_binomial_probability(ix, n, p);
}
The smallest point with positive probability using
the given del is 1 and all points after
point number 19 (counting from the input value
of IMIN) have zero probability.
Cumulative probabilities and indexes
1 0.0000191
2 0.0002003
3 0.0012875
4 0.0059080
5 0.0206938
6 0.0576583
7 0.1315873
8 0.2517219
9 0.4119013
10 0.5880987
11 0.7482781
12 0.8684127
13 0.9423417
14 0.9793062
15 0.9940920
16 0.9987125
17 0.9997997
18 0.9999809
19 1.0000000
20 11.0000000
21 1.0000000
22 7.0000000
23 8.0000000
24 9.0000000
25 9.0000000
26 10.0000000
27 11.0000000
28 11.0000000
29 12.0000000
30 13.0000000
31 19.0000000
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