Provided by: openmpi-doc_1.10.2-8ubuntu1_all 
NAME
MPI_Type_vector - Creates a vector (strided) datatype.
SYNTAX
C Syntax
#include <mpi.h>
int MPI_Type_vector(int count, int blocklength, int stride,
MPI_Datatype oldtype, MPI_Datatype *newtype)
Fortran Syntax
INCLUDE 'mpif.h'
MPI_TYPE_VECTOR(COUNT, BLOCKLENGTH, STRIDE, OLDTYPE, NEWTYPE,
IERROR)
INTEGER COUNT, BLOCKLENGTH, STRIDE, OLDTYPE
INTEGER NEWTYPE, IERROR
C++ Syntax
#include <mpi.h>
Datatype Datatype::Create_vector(int count, int blocklength,
int stride) const
INPUT PARAMETERS
count Number of blocks (nonnegative integer).
blocklength
Number of elements in each block (nonnegative integer).
stride Number of elements between start of each block (integer).
oldtype Old datatype (handle).
OUTPUT PARAMETERS
newtype New datatype (handle).
IERROR Fortran only: Error status (integer).
DESCRIPTION
The function MPI_Type_vector is a general constructor that allows replication of a
datatype into locations that consist of equally spaced blocks. Each block is obtained by
concatenating the same number of copies of the old datatype. The spacing between blocks is
a multiple of the extent of the old datatype.
Example 1: Assume, again, that oldtype has type map {(double, 0), (char, 8)}, with extent
16. A call to MPI_Type_vector(2, 3, 4, oldtype, newtype) will create the datatype with
type map
{(double, 0), (char, 8), (double, 16), (char, 24),
(double, 32), (char, 40),
(double, 64), (char, 72),
(double, 80), (char, 88), (double, 96), (char, 104)}
That is, two blocks with three copies each of the old type, with a stride of 4 elements (4
x 6 bytes) between the blocks.
Example 2: A call to MPI_Type_vector(3, 1, -2, oldtype, newtype) will create the
datatype
{(double, 0), (char, 8), (double, -32), (char, -24),
(double, -64), (char, -56)}
In general, assume that oldtype has type map
{(type(0), disp(0)), ..., (type(n-1), disp(n-1))},
with extent ex. Let bl be the blocklength. The newly created datatype has a type map with
count x bl x n entries:
{(type(0), disp(0)), ..., (type(n-1), disp(n-1)),
(type(0), disp(0) + ex), ..., (type(n-1), disp(n-1) + ex), ...,
(type(0), disp(0) + (bl -1) * ex),...,
(type(n-1), disp(n-1) + (bl -1)* ex),
(type(0), disp(0) + stride * ex),..., (type(n-1),
disp(n-1) + stride * ex), ...,
(type(0), disp(0) + (stride + bl - 1) * ex), ...,
(type(n-1), disp(n-1) + (stride + bl -1) * ex), ...,
(type(0), disp(0) + stride * (count -1) * ex), ...,
(type(n-1), disp(n-1) + stride * (count -1) * ex), ...,
(type(0), disp(0) + (stride * (count -1) + bl -1) * ex), ...,
(type(n-1), disp(n-1) + (stride * (count -1) + bl -1) * ex)}
A call to MPI_Type_contiguous(count, oldtype, newtype) is equivalent to a call to
MPI_Type_vector(count, 1, 1, oldtype, newtype), or to a call to MPI_Type_vector(1, count,
n, oldtype, newtype), n arbitrary.
ERRORS
Almost all MPI routines return an error value; C routines as the value of the function and
Fortran routines in the last argument. C++ functions do not return errors. If the default
error handler is set to MPI::ERRORS_THROW_EXCEPTIONS, then on error the C++ exception
mechanism will be used to throw an MPI::Exception object.
Before the error value is returned, the current MPI error handler is called. By default,
this error handler aborts the MPI job, except for I/O function errors. The error handler
may be changed with MPI_Comm_set_errhandler; the predefined error handler
MPI_ERRORS_RETURN may be used to cause error values to be returned. Note that MPI does not
guarantee that an MPI program can continue past an error.
SEE ALSO
MPI_Type_create_hvector
MPI_Type_hvector