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?

Thanks in advance

```
/***********************************************************
* 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.