VEC_$SUB_MULT_VECTOR_I Domain/OS VEC_$SUB_MULT_VECTOR_I
NAME
vec_$sub_mult_vector_i - subtract two single-precision vectors, multiply
by a third
SYNOPSIS (C)
#include <apollo/base.h>
#include <apollo/vec.h>
void vec_$sub_mult_vector_i(
float *start_vec,
long int &start_inc,
float *sub_vec,
long int &sub_inc,
float *mult_vec,
long int &mult_inc,
long int &length,
float *result_vec,
long int &result_inc)
SYNOPSIS (Pascal)
%include '/sys/ins/base.ins.pas';
%include '/sys/ins/vec.ins.pas';
procedure vec_$sub_mult_vector_i(
in start_vec: univ vec_$real_vector;
in start_inc: integer32;
in sub_vec: univ vec_$real_vector;
in sub_inc: integer32;
in mult_vec: univ vec_$real_vector;
in mult_inc: integer32;
in length: integer32;
out result_vec: univ vec_$real_vector;
in result_inc: integer32);
SYNOPSIS (FORTRAN)
%include '/sys/ins/base.ins.ftn'
%include '/sys/ins/vec.ins.ftn'
parameter (nvec = 10)
real start_vec(nvec), result_vec(nvec), sub_vec(nvec), mult_vec(nvec)
integer*4 length
integer*4 start_inc, sub_inc, mult_inc, result_inc
call vec_$sub_mult_vector_i(start_vec, start_inc, sub_vec, sub_inc,
& mult_vec, mult_inc, length, result_vec, result_inc)
DESCRIPTION
Vec_$sub_mult_vector_i subtracts the vector sub_vec from start_vec, mul-
tiplies the result by mult_vec, and stores the final result in
result_vec.
This call, like all vec_$ calls ending in _i, takes a set of extra stride
arguments, one for every vector argument. The stride arguments determine
which elements in the array are actually processed. For instance, if the
stride for a particular array is set to 3, every third element in the
array will be processed by the routine. The stride arguments need not be
identical. If all stride arguments are set to 1, this call behaves
exactly like the version without the _i in its name.
The calculation performed is as follows: Initialize the counter vari-
ables J, K, L, and M to the low indices of the arrays start_vec, sub_vec,
mult_vec, and result_vec. In Fortran, the low index will be 1; in C, it
will be 0; in Pascal, it varies depending on the declaration.
Execute the following equations length times:
result_vec(M) = (start_vec(J) - sub_vec(K)) x mult_vec(L)
J = J + start_inc
K = K + sub_inc
L = L + mult_inc
M = M + result_inc
Note that the multiplication done by this call is point-wise. This call
does not perform matrix multiplication, since the product of two vectors
is another vector of the same magnitude.
start_vec
A vector to be subtracted from.
start_inc
The stride for start_vec.
sub_vec
A vector to be subtracted.
sub_inc
The stride for sub_vec.
mult_vec
A multiplicand vector.
mult_inc
The stride for mult_vec.
length
The number of elements to be operated on; normally the same as the
number of elements in the vectors.
result_vec
The vector created by subtracting sub_vec from start_vec and multi-
plying the result by mult_vec.
result_inc
The stride for result_vec.
NOTES
When vec_$sub_mult_vector_i is used to operate on matrixes in C and Pas-
cal, start_vec, sub_vec, mult_vec, and result_vec are row vectors; in
FORTRAN, they are column vectors.
As in all the vec_$ calls, the result array must not overlap any of the
input arrays; the result array may be identical to an input, but must not
contain any subset of it. Because of pipelining, using overlapping
input and output arrays may cause incorrect results.
SEE ALSO
vec_$add_mult_vector, vec_$mult_add_vector, vec_$mult_sub_vector,
vec_$mult_rsub_vector, vec_$add_add_vector, vec_$sub_add_vector,
vec_$mult_mult_vector, vec_$sub_mult_vector, vec_$dsub_mult_vector,
vec_$dsub_mult_vector_i, vec_$isub_mult_vector, vec_$isub_mult_vector_i,
vec_$isub_mult_vector16, vec_$isub_mult_vector16_i.