# How to combine subarrays in a Cartesian configuration using mpi_gatherv

I am having trouble figuring out how the array transfers work on a system where subarrays of different sizes in each process are sent to a main array in the root process. With the code attached I obtain the following correct output matrix if I run it with 3 processes:

``````0:   1   1   1   1   1   1
1:   1   1   1   1   1   1
2:   1   1   1   1   1   1
3:   1   1   1   1   1   1
4:   2   2   2   2   2   2
5:   2   2   2   2   2   2
6:   2   2   2   2   2   2
7:   3   3   3   3   3   3
8:   3   3   3   3   3   3
9:   3   3   3   3   3   3
``````

Whereas with 4 processes I get:

``````0:   1   1   1   2   2   2
1:   2   2   2   2   2   2
2:   2   2   2   2   2   2
3:   1   1   1  -0  -0  -0
4:   1   1   1  -0  -0  -0
5:   3   3   3   4   4   4
6:   4   4   4   4   4   4
7:   4   4   4   4   4   4
8:  -0  -0  -0  -0  -0  -0
9:  -0  -0  -0  -0  -0  -0
``````

when I expect to get:

``````0:   1   1   1   2   2   2
1:   1   1   1   2   2   2
2:   1   1   1   2   2   2
3:   1   1   1   2   2   2
4:   1   1   1   2   2   2
5:   3   3   3   4   4   4
6:   3   3   3   4   4   4
7:   3   3   3   4   4   4
8:   3   3   3   4   4   4
9:   3   3   3   4   4   4
``````

The code is as follows:

``````#include <mpi.h>
#include <stdio.h>
#include <stdlib.h>

#define ROWS                    10
#define COLUMNS                 6

float** allocate_fmatrix (int row, int column)
{
float **matrix = NULL;
int i;

matrix = (float **) malloc (row * sizeof(float *));
if (matrix != NULL) {
matrix[0] = (float *) malloc (row * column * sizeof(float));
if (matrix[0] != NULL) {
for (i = 1; i < row; i++) {
matrix[i] = matrix[0] + i * column;
}
}
else {
free (matrix);
matrix = NULL;
}
}
else {
matrix = NULL;
}
return matrix;
}

int main (int argc, char* argv[])
{
int   num_procs, my_rank;
int   i, j, root = 0;
int   *subarr_rows, *subarr_cols;
int   *my_subarr_rows, *my_subarr_cols;
int   *subarr_rows_starts, *subarr_cols_starts;
int   my_subarr_rows_starts, my_subarr_cols_starts;
int   *counts, *displs;
int   *sizes, *subsizes, *starts;
int   ndims = 2;
int   *coords, *dims, *periods, reorder;
int   cart_group_rank;
float **matrix = NULL;
MPI_Datatype sendsubarray;
MPI_Datatype recvsubarray;
MPI_Datatype resizedrecvsubarray;
MPI_Comm     comm_cart;
MPI_Group    mpi_cart_group;

// Start MPI:
MPI_Init (&argc, &argv);
MPI_Comm_rank (MPI_COMM_WORLD, &my_rank);
MPI_Comm_size (MPI_COMM_WORLD, &num_procs);

// Do the Cartesian MPI process decomposition:
coords             = (int *) malloc (ndims     * sizeof(int));
dims               = (int *) malloc (ndims     * sizeof(int));
periods            = (int *) malloc (ndims     * sizeof(int));
dims[0]    = 0;
dims[1]    = 0;
MPI_Dims_create (num_procs, ndims, dims);
periods[0] = 1;
periods[1] = 1;
reorder    = 0;
MPI_Cart_create (MPI_COMM_WORLD, ndims, dims, periods, reorder, &comm_cart);
MPI_Comm_group (comm_cart, &mpi_cart_group);
MPI_Group_rank (mpi_cart_group, &cart_group_rank);
MPI_Cart_coords (comm_cart, cart_group_rank, ndims, coords);

// Calculate the number of rows or columns per node (or MPI process).
// Then, let every node know the number of rows or columns at each node.
subarr_rows           = (int *) malloc (num_procs * sizeof(int));
subarr_rows_starts    = (int *) malloc (num_procs * sizeof(int));
my_subarr_rows        = (int *) malloc (dims[0]   * sizeof(int));
subarr_cols           = (int *) malloc (num_procs * sizeof(int));
subarr_cols_starts    = (int *) malloc (num_procs * sizeof(int));
my_subarr_cols        = (int *) malloc (dims[1]   * sizeof(int));
counts                = (int *) malloc (num_procs * sizeof(int));
displs                = (int *) malloc (num_procs * sizeof(int));
sizes                 = (int *) malloc (ndims     * sizeof(int));
subsizes              = (int *) malloc (ndims     * sizeof(int));
starts                = (int *) malloc (ndims     * sizeof(int));

int subarr_rows_factor = coords[0] < (ROWS % dims[0]) ? 1 : 0;
my_subarr_rows[coords[0]] = ROWS / dims[0] + subarr_rows_factor;
MPI_Allgather (&my_subarr_rows[coords[0]], 1, MPI_INT,
&subarr_rows[0], 1, MPI_INT, MPI_COMM_WORLD);
my_subarr_rows_starts = 0;
for (i = 1; i <= coords[0]; i++)
my_subarr_rows_starts += subarr_rows[i - 1];
MPI_Gather (&my_subarr_rows_starts,       1, MPI_INT,
&subarr_rows_starts[my_rank], 1, MPI_INT, root, MPI_COMM_WORLD);

int subarr_cols_factor = coords[1] < (COLUMNS % dims[1]) ? 1 : 0;
my_subarr_cols[coords[1]] = COLUMNS / dims[1] + subarr_cols_factor;
MPI_Allgather (&my_subarr_cols[coords[1]], 1, MPI_INT,
&subarr_cols[0], 1, MPI_INT, MPI_COMM_WORLD);
my_subarr_cols_starts = 0;
for (i = 1; i <= coords[1]; i++)
my_subarr_cols_starts += subarr_cols[i - 1];
MPI_Gather (&my_subarr_cols_starts,       1, MPI_INT,
&subarr_cols_starts[my_rank], 1, MPI_INT, root, MPI_COMM_WORLD);

// Create the subarray type for use by each send node (incl. the root):
sizes[0]    = ROWS;
sizes[1]    = COLUMNS;
subsizes[0] = subarr_rows[my_rank];
subsizes[1] = subarr_cols[my_rank];
starts[0]   = my_subarr_rows_starts;
starts[1]   = my_subarr_cols_starts;
MPI_Type_create_subarray (ndims, sizes, subsizes, starts, MPI_ORDER_C,
MPI_FLOAT, &sendsubarray);
MPI_Type_commit (&sendsubarray);

// Create and populate this node's send subarray:
matrix = allocate_fmatrix (ROWS, COLUMNS);
for (i = 0; i < ROWS; i++)
for (j = 0; j < COLUMNS; j++)
matrix[i][j] = -1.0 * my_rank;
for (i = starts[0]; i < starts[0] + subsizes[0]; i++)
for (j = starts[1]; j < starts[1] + subsizes[1]; j++)
matrix[i][j] = my_rank + 1.0;

// Create the subarray type for use by the receive node (the root):
if (my_rank == root) {
subsizes[0] = 1;
subsizes[1] = 1;
MPI_Type_create_subarray (ndims, sizes, subsizes, starts, MPI_ORDER_C,
MPI_FLOAT, &recvsubarray);
MPI_Type_create_resized (recvsubarray, 0, 1 * sizeof(float),
&resizedrecvsubarray);
MPI_Type_commit (&resizedrecvsubarray);

// Fill in the disposition of each subarray within the root subarray:
for (i = 0; i < num_procs; i++) {
counts[i] = subarr_rows[i] * subarr_cols[i];
displs[i] = subarr_rows_starts[i] * COLUMNS + subarr_cols_starts[i];
}
}

MPI_Gatherv (matrix[0], 1, sendsubarray,
matrix[0], counts, displs, resizedrecvsubarray,
root, MPI_COMM_WORLD);

// Have the root send the main array to the output:
if (my_rank == root) {
for (i = 0; i < ROWS; i++) {
printf ("%3d: ", i);
for (j = 0; j < COLUMNS; j++) {
printf ("%3.0f ", matrix[i][j]);
}
printf ("\n");
}
}

// Free allocatins and exit:
if (my_rank == 0) MPI_Type_free (&resizedrecvsubarray);
MPI_Type_free (&sendsubarray);
free (matrix);
MPI_Finalize();
return 0;
}
``````

I don't understand why this works for whole row subarrays and not for the Cartesian subarrays.

As always, any help will be greatly appreciated.

-
what have you tried to figure out the problem? Did you print the subarray dimensions for each process, etc... – steabert Mar 26 '12 at 7:59
Using gather and scatter for pieces of a 2d array is described in some detail in the answer to this question - stackoverflow.com/questions/9269399/… . The biggest problem I see in your code right now is that the 2d array isn't allocated in one contiguous block, which then causes problems when you try to take slices of that data. – Jonathan Dursi Mar 26 '12 at 11:33
I have tried changing the array allocation strategy (including the one in your link) all to no avail. On inspecting the memory with the DDT parallel debugger I can see the matrix allocation is continuous on all processes, and yet my code still fails. I have now reached the point where I have 2 working code samples: one for row subarrays and one for columnar subarrays, but when combining them (resulting in the code I posted) it does not work as intended, not for all configs. I am beginning to think I will have to redesign my Cartesian distributing program using something other than MPI_Gatherv – Frank Christiny Mar 27 '12 at 2:46