# Dynamic Allocation of huge 3D arrays

I am working on a project where I need to create a 3D array, some 2D and 1D arrays. The 3D array represents discrete co-ordinates in space and I need lots of points for my problem. The array size will be around 2000*2000*2000. I need store 'double' values in these arrays. Can anyone suggest an efficient scheme to implement this in C?

``````/***********************************************************
*  Copyright Univ. of Texas M.D. Anderson Cancer Center
*  1992.
*
*  Some routines modified from Numerical Recipes in C,
*  including error report, array or matrix declaration
*  and releasing.
****/
#include <stdlib.h>
#include <stdio.h>
#include <math.h>
#include <malloc.h>

/***********************************************************
*  Report error message to stderr, then exit the program
*  with signal 1.
****/
void nrerror(char error_text[])

{
fprintf(stderr,"%s\n",error_text);
fprintf(stderr,"...now exiting to system...\n");
exit(1);
}

/***********************************************************
*  Allocate an array with index from nl to nh inclusive.
*
*  Original matrix and vector from Numerical Recipes in C
*  don't initialize the elements to zero. This will
*  be accomplished by the following functions.
****/
double *AllocVector(short nl, short nh)
{
double *v;
short i;

v=(double *)malloc((unsigned) (nh-nl+1)*sizeof(double));
if (!v) nrerror("allocation failure in vector()");

v -= nl;
for(i=nl;i<=nh;i++) v[i] = 0.0;   /* init. */
return v;
}

/***********************************************************
*  Allocate a matrix with row index from nrl to nrh
*  inclusive, and column index from ncl to nch
*  inclusive.
****/
double **AllocMatrix(short nrl,short nrh,
short ncl,short nch)
{
short i,j;
double **m;

m=(double **) malloc((unsigned) (nrh-nrl+1)
*sizeof(double*));
if (!m) nrerror("allocation failure 1 in matrix()");
m -= nrl;

for(i=nrl;i<=nrh;i++) {
m[i]=(double *) malloc((unsigned) (nch-ncl+1)
*sizeof(double));
if (!m[i]) nrerror("allocation failure 2 in matrix()");
m[i] -= ncl;
}

for(i=nrl;i<=nrh;i++)
for(j=ncl;j<=nch;j++) m[i][j] = 0.0;
return m;
}

/***********************************************************
*  Allocate a 3D array with x index from nxl to nxh
*  inclusive, y index from nyl to nyh and z index from nzl to nzh
*  inclusive.
****/
double ***Alloc3D(short nxl,short nxh,
short nyl,short nyh,
short nzl, short nzh)
{
double ***t;
short i,j,k;

t=(double ***) malloc((unsigned) (nxh-nxl+1)*sizeof(double **));
if (!t) nrerror("allocation failure 1 in matrix()");
t -= nxl;

for(i=nxl;i<=nxh;i++) {
t[i]=(double **) malloc((unsigned) (nyh-nyl+1)*sizeof(double *));
if (!t[i]) nrerror("allocation failure 2 in matrix()");
t[i] -= nyl;
for(j=nyl;j<=nyh;j++) {
t[i][j]=(double *) malloc((unsigned) (nzh-nzl+1)*sizeof(double));
if (!t[i][j]) nrerror("allocation failure 3 in matrix()");
t[i][j] -= nzl;}

}

for(i=nxl;i<=nxh;i++)
for(j=nyl;j<=nyh;j++)
for(k=nzl; k<=nzh;k++) t[i][j][k] = 0.0;
return t;
}
/***********************************************************
*Index to 3D array.
****/
long index(int x, int y, int z, int Size)
{
return (Size*Size*x + Size*y + z);
}
/***********************************************************
*  Release the memory.
****/
void FreeVector(double *v,short nl,short nh)
{
free((char*) (v+nl));
}

/***********************************************************
*  Release the memory.
****/
void FreeMatrix(double **m,short nrl,short nrh,
short ncl,short nch)
{
short i;

for(i=nrh;i>=nrl;i--) free((char*) (m[i]+ncl));
free((char*) (m+nrl));
}

/***********************************************************
*  Release the memory.
****/
void Free3D(double ***t,short nxl,short nxh,
short nyl,short nyh, short nzl, short nzh)
{
short i,j;

for(i=nxh;i>=nxl;i--)
{for(j=nyl;j>=nyl;j--) free((char*) (t[i][j]+nzl));
free((char*) (t[i]+nyl));
}
free((char*) (t+nxl));
}

***********************************************************************************

void InitOutputData(InputStruct In_Parm, OutStruct * Out_Ptr)
{
short nz = In_Parm.nz;
short nr = In_Parm.nr;
short na = In_Parm.na;
short nl = In_Parm.num_layers;
short size = nr/2*nr/2*nz;
/* remember to use nl+2 because of 2 for ambient. */

if(nz<=0 || nr<=0 || na<=0 || nl<=0)
nrerror("Wrong grid parameters.\n");

/* Init pure numbers. */
Out_Ptr->Rsp = 0.0;
Out_Ptr->Rd  = 0.0;
Out_Ptr->A   = 0.0;
Out_Ptr->Tt  = 0.0;

/* Allocate the arrays and the matrices. */
//Out_Ptr->Rd_ra = AllocMatrix(0,nr-1,0,na-1);
//Out_Ptr->Rd_r  = AllocVector(0,nr-1);
//Out_Ptr->Rd_a  = AllocVector(0,na-1);

Out_Ptr->A_xyz1 = AllocVector(0,size-1);
Out_Ptr->A_xyz2 = AllocVector(0,size-1);
Out_Ptr->A_xyz3 = AllocVector(0,size-1);
Out_Ptr->A_xyz4 = AllocVector(0,size-1);
Out_Ptr->A_xz  = AllocMatrix(0,nr-1,0,nz-1);
Out_Ptr->A_z   = AllocVector(0,nz-1);
Out_Ptr->A_l   = AllocVector(0,nl+1);

Out_Ptr->Tt_ra = AllocMatrix(0,nr-1,0,na-1);
Out_Ptr->Tt_r  = AllocVector(0,nr-1);
Out_Ptr->Tt_a  = AllocVector(0,na-1);
}
``````

Above is the code for allocating the arrays and the function to call them. The call which fails is 'Out_Ptr->A_xyz1 = AllocVector(0,size-1);' when size is more than approx. 7000.

-
Is it going to be a sparse array? –  tbert Aug 2 '12 at 13:07
Do the coordinates represent a regular grid? i.e. Must you store the values or can they be calculated when needed from a grid-spacing within an extents rectangle? –  acraig5075 Aug 2 '12 at 13:12
Do you need to access the array mostly in sequence or random access? You could memory-map parts of a big file to store the values. Can't do random access then though. –  Joachim Pileborg Aug 2 '12 at 13:18
What's wrong with malloc() ? I'm serious. For such large sizes malloc uses mmap() to allocate a private anonymous mapping, which is as efficient as you can be. I fail to understand what the problem is. –  Antoine Mathys Aug 2 '12 at 13:57
Do you realize that you're trying to allocate 2000x2000x2000x8 = 64 GB? No wonder you run out of memory! –  Clark Gaebel Aug 2 '12 at 14:41

This is a perfect use case for mmap! Your array is 64 GB - much too big to fit in RAM all at once. Luckily, we can force the kernel to do all the heavy lifting for us.

Here's some (admittedly untested) code:

``````#include <sys/mman.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include <string.h>
#include <stdio.h>

#define ARRAY_SIZE ((off_t)2000*2000*2000*8)

static inline off_t idx(off_t x, off_t y, off_t z)
{
return 2000*2000*x + 2000*y + z;
}

int main()
{
int fd = open("my_huge_array.dat", O_RDWR | O_CREAT | O_TRUNC);

// We have to write to the end of the file for the size to be set properly.
lseek(fd, ARRAY_SIZE - 1, SEEK_SET);
write(fd, "", 1);

double* my_huge_array = mmap(NULL, ARRAY_SIZE, PROT_READ | PROT_WRITE, MAP_SHARED, fd, 0);

// Now play with the array!
my_huge_array[idx(4, 7, 9)] = 12;
my_huge_array[idx(0, 0, 0)] = my_huge_array[idx(4, 7, 9)] * 2;

// Close it up. Don't leak your fd's!
munmap(my_huge_array, ARRAY_SIZE);
close(fd);
remove("my_huge_array.dat");
return 0;
}
``````
-
What if I need to keep the map open till my code ends. Run time now is around 50hrs. Is that okay? Or do I need to close it and open with every write. –  pitc Aug 2 '12 at 16:15
You can close it whenever you want. 50 hours is okay. The kernel manages all memory -> disk activity with what I assume is an LRU cache. –  Clark Gaebel Aug 2 '12 at 19:38
@pitc - another advantage of mmap, every 10-15 minutes have it flush to disk, and serialize any other data values you need. Then if you have a failure you could write code that recovers from the saved point –  Martin Beckett Aug 2 '12 at 21:20
Thanks let me try mmap()and get back to you. –  pitc Aug 3 '12 at 9:39
How do I create the map if I want to call the creation from another function, keep the map alive while some other functions add data to it via pointers and then close the map later, using another function? –  pitc Aug 3 '12 at 10:01

If they are a fixed size (or at least a fixed maximum size) at run time and they are bigger than physical RAM then you may as well use a memory mapped file. The access is at least as quick as RAM+swap and you get the data serialised to disk for free. You can also map views of regions (ie windows) of mapped files that are overall larger than your address space.

If you need a large number of cells because you need high detail in some regions, but not uniformly, you could consider an octree. Then you can store progressively finer resolution in some parts and you have the option to reorder to optimise access to regions that are nearby in 3D - this is very common in things like CFD or medical imaging.

-
malloc is not able to allocate such a huge chunk. I have never used mmap(). let me give it a try and reply. Thanks a lot. –  pitc Aug 2 '12 at 14:13
pitc, if you are on a 32bit platform the 2000^3 is bigger than the address space, so you either have to deal with planes/rows/cols separately or use mapped views, or switch to 64bit! –  Martin Beckett Aug 2 '12 at 14:16
Yeah got that part, but I was not able to even allocate a 100*100*100 array using malloc(). Now, I am thinking problem is not with malloc. I will add my code to the post. –  pitc Aug 2 '12 at 14:23
The problem is malloc needs a single uninterupted block of memory that big! You need to malloc each 2d plane (or possible even each row) separately and then make an array of arrays. That way maloc can finf space for 100x100 blocks of memory anywhere –  Martin Beckett Aug 2 '12 at 14:28
Tried that too. Look at Alloc 3D. Same problem when I try to use that function too. –  pitc Aug 2 '12 at 14:33