CuPBoP/examples/btree/main.c

// # ifdef __cplusplus
// extern "C" {
// # endif

//========================================================================================================================================================================================================200
//======================================================================================================================================================150
//====================================================================================================100
//==================================================50

//========================================================================================================================================================================================================200
//	INFORMATION
//========================================================================================================================================================================================================200

//======================================================================================================================================================150
//	UPDATE
//======================================================================================================================================================150

// 2009; Amittai Aviram; entire code written in C;
// 2010; Jordan Fix and Andrew Wilkes; code converted to CUDA;
// 2011.10; Lukasz G. Szafaryn; code converted to portable form, to C, OpenMP,
// CUDA, PGI versions; 2011.12; Lukasz G. Szafaryn; Split different versions for
// Rodinia. 2011.12; Lukasz G. Szafaryn; code converted to OpenCL; 2012.10; Ke
// Wang; Change it to non-interactive mode. Use command option read command from
// file. And also add output for easy verification among different platforms and
// devices.Merged into Rodinia main distribution 2.2.
//======================================================================================================================================================150
//	DESCRIPTION
//======================================================================================================================================================150

// Description

//======================================================================================================================================================150
//	USE
//======================================================================================================================================================150

// EXAMPLE:
// ./b+tree file ./input/mil.txt command ./command.txt
// ...then enter any of the following commands after the prompt > :
// f <x>  -- Find the value under key <x>
// p <x> -- Print the path from the root to key k and its associated value
// t -- Print the B+ tree
// l -- Print the keys of the leaves (bottom row of the tree)
// v -- Toggle output of pointer addresses ("verbose") in tree and leaves.
// k <x> -- Run <x> bundled queries on the CPU and GPU (B+Tree) (Selects random
// values for each search) j <x> <y> -- Run a range search of <x> bundled
// queries on the CPU and GPU (B+Tree) with the range of each search of size <y>
// x <z> -- Run a single search for value z on the GPU and CPU
// y <a> <b> -- Run a single range search for range a-b on the GPU and CPU
// q -- Quit. (Or use Ctl-D.)

//======================================================================================================================================================150
//	END
//======================================================================================================================================================150

//========================================================================================================================================================================================================200
//	DEFINE/INCLUDE
//========================================================================================================================================================================================================200

//======================================================================================================================================================150
//	LIBRARIES
//======================================================================================================================================================150

#include <limits.h> // (in directory known to compiler)			needed by INT_MIN, INT_MAX
#include <stdio.h> // (in directory known to compiler)			needed by printf, stderr
// #include <sys/time.h> //
// (in directory known to compiler)			needed by ???
#include <math.h>   // (in directory known to compiler)			needed by log, pow
#include <string.h> // (in directory known to compiler)			needed by memset

//======================================================================================================================================================150
//	COMMON
//======================================================================================================================================================150

#include "./common.h" // (in directory provided here)

//======================================================================================================================================================150
//	DEFINE
//======================================================================================================================================================150

//======================================================================================================================================================150
//	UTILITIES
//======================================================================================================================================================150

#include "./util/num/num.h"     // (in directory provided here)
#include "./util/timer/timer.h" // (in directory provided here)

//======================================================================================================================================================150
//	KERNEL HEADERS
//======================================================================================================================================================150

#include "./kernel/kernel_gpu_cuda_wrapper.h"   // (in directory provided here)
#include "./kernel/kernel_gpu_cuda_wrapper_2.h" // (in directory provided here)

//======================================================================================================================================================150
//	HEADER
//======================================================================================================================================================150

#include "./main.h" // (in directory provided here)

//======================================================================================================================================================150
//	END
//======================================================================================================================================================150

//========================================================================================================================================================================================================200
//	VARIABLES
//========================================================================================================================================================================================================200

// general variables
knode *knodes;
record *krecords;
char *mem;
long freeptr;
long malloc_size;
long size;
long maxheight;

/* The order determines the maximum and minimum
 * number of entries (keys and pointers) in any
 * node.  Every node has at most order - 1 keys and
 * at least (roughly speaking) half that number.
 * Every leaf has as many pointers to data as keys,
 * and every internal node has one more pointer
 * to a subtree than the number of keys.
 * This global variable is initialized to the
 * default value.
 */
int order = DEFAULT_ORDER;

/* The queue is used to print the tree in
 * level order, starting from the root
 * printing each entire rank on a separate
 * line, finishing with the leaves.
 */
node *queue = NULL;

/* The user can toggle on and off the "verbose"
 * property, which causes the pointer addresses
 * to be printed out in hexadecimal notation
 * next to their corresponding keys.
 */
bool verbose_output = false;

//========================================================================================================================================================================================================200
//	FUNCTIONS
//========================================================================================================================================================================================================200

//======================================================================================================================================================150
//	Components
//======================================================================================================================================================150

void list_init(list_t *l, int32_t (*compare)(const void *key, const void *with),
               void (*datum_delete)(void *)) {
  l->head = l->tail = NULL;
  l->length = 0;
  l->compare = compare;
  l->datum_delete = datum_delete;
}

void list_delete(list_t *l) {

  list_item_t *li, *del;

  for (li = l->head; li;) {

    del = li;
    li = li->next;
    list_item_delete(del, l->datum_delete);
  }

  l->head = l->tail = NULL;
  l->length = 0;
}

void list_reset(list_t *l) { list_delete(l); }

void list_insert_item_head(list_t *l, list_item_t *i) {
  if (l->head) {
    i->next = l->head;
    l->head->pred = i;
    l->head = i;
    l->head->pred = NULL;
  } else {
    l->head = l->tail = i;
    i->next = i->pred = NULL;
  }
  l->length++;
}

void list_insert_item_tail(list_t *l, list_item_t *i) {
  if (l->head) {
    l->tail->next = i;
    i->pred = l->tail;
    i->next = NULL;
    l->tail = i;
  } else {
    l->head = l->tail = i;
    i->next = i->pred = NULL;
  }
  l->length++;
}

void list_insert_item_before(list_t *l, list_item_t *next, list_item_t *i) {
  /* Assume next is actually in the list! */
  /* If it's not, we may lose the list.   */
  if (l->head == next) {
    i->next = next;
    i->pred = NULL;
    l->head = i;
    next->pred = i;
  } else {
    i->next = next;
    i->pred = next->pred;
    next->pred->next = i;
    next->pred = i;
  }
  l->length++;
}

void list_insert_item_after(list_t *l, list_item_t *pred, list_item_t *i) {
  /* Assume pred is actually in the list! */
  /* If it's not, we may lose the list.   */
  if (l->tail == pred) {
    i->pred = pred;
    i->next = NULL;
    l->tail = i;
    pred->next = i;
  } else {
    i->pred = pred;
    i->next = pred->next;
    pred->next->pred = i;
    pred->next = i;
  }
  l->length++;
}

void list_insert_item_sorted(list_t *l, list_item_t *i) {
  list_item_t *itr;

  if (l->head) {
    for (itr = l->head; itr && l->compare(list_item_get_datum(i),
                                          list_item_get_datum(itr)) < 0;
         itr = itr->next)
      ;
    if (itr) {
      i->next = itr;
      i->pred = itr->pred;
      itr->pred = i;
      i->pred->next = i;
    } else {
      l->tail->next = i;
      i->pred = l->tail;
      i->next = NULL;
      l->tail = i;
    }
  } else {
    l->head = l->tail = i;
    i->pred = i->next = NULL;
  }
  l->length++;
}

void list_insert_head(list_t *l, void *v) {
  list_item_t *i;
  i = (list_item_t *)malloc(sizeof(*i));
  list_item_init(i, v);
  if (l->head) {
    i->next = l->head;
    l->head->pred = i;
    l->head = i;
    l->head->pred = NULL;
  } else {
    l->head = l->tail = i;
    i->next = i->pred = NULL;
  }
  l->length++;
}

void list_insert_tail(list_t *l, void *v) {
  list_item_t *i;

  i = (list_item_t *)malloc(sizeof(*i));
  list_item_init(i, v);
  if (l->head) {
    l->tail->next = i;
    i->pred = l->tail;
    i->next = NULL;
    l->tail = i;
  } else {
    l->head = l->tail = i;
    i->next = i->pred = NULL;
  }
  l->length++;
}

void list_insert_before(list_t *l, list_item_t *next, void *v) {
  list_item_t *i;

  i = (list_item_t *)malloc(sizeof(*i));
  list_item_init(i, v);

  /* Assume next is actually in the list! */
  /* If it's not, we may lose the list.   */
  if (l->head == next) {
    i->next = next;
    i->pred = NULL;
    l->head = i;
    next->pred = i;
  } else {
    i->next = next;
    i->pred = next->pred;
    next->pred->next = i;
    next->pred = i;
  }
  l->length++;
}

void list_insert_after(list_t *l, list_item_t *pred, void *v) {
  list_item_t *i;

  i = (list_item_t *)malloc(sizeof(*i));
  list_item_init(i, v);

  /* Assume pred is actually in the list! */
  /* If it's not, we may lose the list.   */
  if (l->tail == pred) {
    i->pred = pred;
    i->next = NULL;
    l->tail = i;
    pred->next = i;
  } else {
    i->pred = pred;
    i->next = pred->next;
    pred->next->pred = i;
    pred->next = i;
  }
  l->length++;
}

void list_insert_sorted(list_t *l, void *v) {
  list_item_t *itr;
  list_item_t *i;

  i = (list_item_t *)malloc(sizeof(*i));
  list_item_init(i, v);

  if (l->head) {
    for (itr = l->head; itr && l->compare(list_item_get_datum(i),
                                          list_item_get_datum(itr)) < 0;
         itr = itr->next)
      ;
    if (itr) {
      i->next = itr;
      i->pred = itr->pred;
      itr->pred = i;
      i->pred->next = i;
    } else {
      l->tail->next = i;
      i->pred = l->tail;
      i->next = NULL;
      l->tail = i;
    }
  } else {
    l->head = l->tail = i;
    i->pred = i->next = NULL;
  }
  l->length++;
}

void list_remove_item(list_t *l, list_item_t *i) {
  if (i == l->head) {
    l->head = l->head->next;
    if (l->head)
      l->head->pred = NULL;
    else
      l->tail = NULL;
  } else if (i == l->tail) {
    l->tail = l->tail->pred;
    l->tail->next = NULL;
  } else {
    i->pred->next = i->next;
    i->next->pred = i->pred;
  }
  l->length--;
  list_item_delete(i, l->datum_delete);
}

void list_remove_head(list_t *l) { list_remove_item(l, l->head); }

void list_remove_tail(list_t *l) { list_remove_item(l, l->tail); }

list_item_t *list_find_item(list_t *l, void *datum) {
  list_item_t *li;

  for (li = l->head; li && l->compare(datum, list_item_get_datum(li));
       li = li->next)
    ;

  return li;
}

list_item_t *list_get_head_item(list_t *l) { return l->head; }

list_item_t *list_get_tail_item(list_t *l) { return l->tail; }

void *list_find(list_t *l, void *datum) {
  list_item_t *li;

  for (li = l->head; li && l->compare(datum, list_item_get_datum(li));
       li = li->next)
    ;

  return li ? li->datum : NULL;
}

void *list_get_head(list_t *l) { return l->head ? l->head->datum : NULL; }

void *list_get_tail(list_t *l) { return l->tail ? l->tail->datum : NULL; }

uint32_t list_get_length(list_t *l) { return l->length; }

bool list_is_empty(list_t *l) { return (l->length == 0); }

bool list_not_empty(list_t *l) { return (l->length != 0); }

void list_visit_items(list_t *l, void (*visitor)(void *v)) {
  list_item_t *li;

  for (li = l->head; li; li = li->next)
    visitor(list_item_get_datum(li));
}

void list_item_init(list_item_t *li, void *datum) {
  li->pred = li->next = NULL;
  li->datum = datum;
}

void list_item_delete(list_item_t *li, void (*datum_delete)(void *datum)) {
  if (datum_delete) {
    datum_delete(li->datum);
  }

  free(li);
}

void *list_item_get_datum(list_item_t *li) { return li->datum; }

void list_iterator_init(list_t *l, list_iterator_t *li) {
  *li = l ? l->head : NULL;
}

void list_iterator_delete(list_iterator_t *li) { *li = NULL; }

void list_iterator_next(list_iterator_t *li) {
  if (*li)
    *li = (*li)->next;
}

void list_iterator_prev(list_iterator_t *li) {
  if (*li)
    *li = (*li)->pred;
}

void *list_iterator_get_datum(list_iterator_t *li) {
  return *li ? (*li)->datum : NULL;
}

bool list_iterator_is_valid(list_iterator_t *li) { return (*li != NULL); }

void list_reverse_iterator_init(list_t *l, list_reverse_iterator_t *li) {
  *li = l ? l->tail : NULL;
}

void list_reverse_iterator_delete(list_reverse_iterator_t *li) { *li = NULL; }

void list_reverse_iterator_next(list_reverse_iterator_t *li) {
  if (*li)
    *li = (*li)->pred;
}

void list_reverse_iterator_prev(list_reverse_iterator_t *li) {
  if (*li)
    *li = (*li)->next;
}

void *list_reverse_iterator_get_datum(list_reverse_iterator_t *li) {
  return *li ? (*li)->datum : NULL;
}

bool list_reverse_iterator_is_valid(list_reverse_iterator_t *li) {
  return (li != NULL);
}

//======================================================================================================================================================150
// OUTPUT AND UTILITIES
//======================================================================================================================================================150

/*   */
void *kmalloc(int size) {

  // printf("size: %d, current offset: %p\n",size,freeptr);
  void *r = (void *)freeptr;
  freeptr += size;
  if (freeptr > malloc_size + (long)mem) {
    printf("Memory Overflow\n");
    exit(1);
  }
  return r;
}

// transforms the current B+ Tree into a single, contiguous block of memory to
// be used on the GPU
long transform_to_cuda(node *root, bool verbose) {

  struct timeval one, two;
  double time;
  gettimeofday(&one, NULL);
  long max_nodes = (long)(pow(order, log(size) / log(order / 2.0) - 1) + 1);
  malloc_size = size * sizeof(record) + max_nodes * sizeof(knode);
  mem = (char *)malloc(malloc_size);
  if (mem == NULL) {
    printf("Initial malloc error\n");
    exit(1);
  }
  freeptr = (long)mem;

  krecords = (record *)kmalloc(size * sizeof(record));
  // printf("%d records\n", size);
  knodes = (knode *)kmalloc(max_nodes * sizeof(knode));
  // printf("%d knodes\n", max_nodes);

  queue = NULL;
  enqueue(root);
  node *n;
  knode *k;
  int i;
  long nodeindex = 0;
  long recordindex = 0;
  long queueindex = 0;
  knodes[0].location = nodeindex++;

  while (queue != NULL) {
    n = dequeue();
    k = &knodes[queueindex];
    k->location = queueindex++;
    k->is_leaf = n->is_leaf;
    k->num_keys = n->num_keys + 2;
    // start at 1 because 0 is set to INT_MIN
    k->keys[0] = INT_MIN;
    k->keys[k->num_keys - 1] = INT_MAX;
    for (i = k->num_keys; i < order; i++)
      k->keys[i] = INT_MAX;
    if (!k->is_leaf) {
      k->indices[0] = nodeindex++;
      // if(k->indices[0]>3953){
      // printf("ERROR: %d\n", k->indices[0]);
      // }
      for (i = 1; i < k->num_keys - 1; i++) {
        k->keys[i] = n->keys[i - 1];
        enqueue((node *)n->pointers[i - 1]);
        k->indices[i] = nodeindex++;
        // if(k->indices[i]>3953){
        // printf("ERROR 1: %d\n", k->indices[i]);
        // }
        // knodes[nodeindex].location = nodeindex++;
      }
      // for final point of n
      enqueue((node *)n->pointers[i - 1]);
    } else {
      k->indices[0] = 0;
      for (i = 1; i < k->num_keys - 1; i++) {
        k->keys[i] = n->keys[i - 1];
        krecords[recordindex].value = ((record *)n->pointers[i - 1])->value;
        k->indices[i] = recordindex++;
        // if(k->indices[i]>3953){
        // printf("ERROR 2: %d\n", k->indices[i]);
        // }
      }
    }

    k->indices[k->num_keys - 1] = queueindex;
    // if(k->indices[k->num_keys-1]>3953){
    // printf("ERROR 3: %d\n", k->indices[k->num_keys-1]);
    // }

    if (verbose) {
      printf("Successfully created knode with index %d\n", k->location);
      printf("Is Leaf: %d, Num Keys: %d\n", k->is_leaf, k->num_keys);
      printf("Pointers: ");
      for (i = 0; i < k->num_keys; i++)
        printf("%d | ", k->indices[i]);
      printf("\nKeys: ");
      for (i = 0; i < k->num_keys; i++)
        printf("%d | ", k->keys[i]);
      printf("\n\n");
    }
  }
  long mem_used = size * sizeof(record) + (nodeindex) * sizeof(knode);
  if (verbose) {
    for (i = 0; i < size; i++)
      printf("%d ", krecords[i].value);
    printf("\nNumber of records = %d, sizeof(record)=%d, total=%d\n", size,
           sizeof(record), size * sizeof(record));
    printf("Number of knodes = %d, sizeof(knode)=%d, total=%d\n", nodeindex,
           sizeof(knode), (nodeindex) * sizeof(knode));
    printf("\nDone Transformation. Mem used: %d\n", mem_used);
  }
  gettimeofday(&two, NULL);
  double oneD = one.tv_sec + (double)one.tv_usec * .000001;
  double twoD = two.tv_sec + (double)two.tv_usec * .000001;
  time = twoD - oneD;
  printf("Tree transformation took %f\n", time);

  return mem_used;
}

/*   */
list_t *findRange(node *root, int start, int end) {

  int i;
  node *c = find_leaf(root, start, false);

  if (c == NULL)
    return NULL;

  list_t *retList = (list_t *)malloc(sizeof(list_t));
  list_init(retList, NULL, NULL);

  int counter = 0;
  bool cont = true;
  while (cont && c != 0) {
    cont = false;
    for (i = 0; i < c->num_keys; i++) {
      if (c->keys[i] >= start && c->keys[i] <= end) {
        // list_insert_tail(retList,(record *)c->pointers[i]);
        counter++;
        cont = true;
      } else {
        cont = false;
        break;
      }
    }
    c = (node *)c->pointers[order - 1];
  }
  return retList;
}

/* First message to the user. */
void usage_1(void) {

  printf("B+ Tree of Order %d.\n", order);
  printf("\tAmittai Aviram -- amittai.aviram@yale.edu  Version %s\n", Version);
  printf("\tfollowing Silberschatz, Korth, Sidarshan, Database Concepts, 5th "
         "ed.\n\n");
  printf("To build a B+ tree of a different order, start again and enter the "
         "order\n");
  printf("as an integer argument:  bpt <order>.  ");
  printf("3 <= order <=20\n");
  printf("To start with input from a file of newline-delimited integers, start "
         "again and enter\n");
  printf("the order followed by the filename:  bpt <order> <inputfile>.\n");
}

/* Second message to the user. */
void usage_2(void) {

  printf("Enter any of the following commands after the prompt > :\n");
  printf("\ti <k>  -- Insert <k> (an integer) as both key and value).\n");
  printf("\tf <k>  -- Find the value under key <k>.\n");
  printf("\tp <k> -- Print the path from the root to key k and its associated "
         "value.\n");
  printf("\td <k>  -- Delete key <k> and its associated value.\n");
  printf("\tx -- Destroy the whole tree.  Start again with an empty tree of "
         "the same order.\n");
  printf("\tt -- Print the B+ tree.\n");
  printf("\tl -- Print the keys of the leaves (bottom row of the tree).\n");
  printf("\tv -- Toggle output of pointer addresses (\"verbose\") in tree and "
         "leaves.\n");
  printf("\tq -- Quit. (Or use Ctl-D.)\n");
  printf("\t? -- Print this help message.\n");
}

/* Helper function for printing the tree out.  See print_tree. */
void enqueue(node *new_node) {
  node *c;
  if (queue == NULL) {
    queue = new_node;
    queue->next = NULL;
  } else {
    c = queue;
    while (c->next != NULL) {
      c = c->next;
    }
    c->next = new_node;
    new_node->next = NULL;
  }
}

/* Helper function for printing the tree out.  See print_tree. */
node *dequeue(void) {
  node *n = queue;
  queue = queue->next;
  n->next = NULL;
  return n;
}

/* Prints the bottom row of keys of the tree (with their respective pointers, if
 * the verbose_output flag is set. */
void print_leaves(node *root) {
  int i;
  node *c = root;
  if (root == NULL) {
    printf("Empty tree.\n");
    return;
  }
  while (!c->is_leaf)
    c = (node *)c->pointers[0];
  while (true) {
    for (i = 0; i < c->num_keys; i++) {
      if (verbose_output)
        // printf("%x ", (unsigned int)c->pointers[i]);
        printf("%d ", c->keys[i]);
    }
    if (verbose_output)
      // printf("%x ", (unsigned int)c->pointers[order - 1]);
      if (c->pointers[order - 1] != NULL) {
        printf(" | ");
        c = (node *)c->pointers[order - 1];
      } else
        break;
  }
  printf("\n");
}

/* Utility function to give the height of the tree, which length in number of
 * edges of the path from the root to any leaf. */
int height(node *root) {
  int h = 0;
  node *c = root;
  while (!c->is_leaf) {
    c = (node *)c->pointers[0];
    h++;
  }
  return h;
}

/* Utility function to give the length in edges of the path from any node to the
 * root. */
int path_to_root(node *root, node *child) {
  int length = 0;
  node *c = child;
  while (c != root) {
    c = c->parent;
    length++;
  }
  return length;
}

/* Prints the B+ tree in the command line in level (rank) order, with the keys
 * in each node and the '|' symbol to separate nodes. With the verbose_output
 * flag set. the values of the pointers corresponding to the keys also appear
 * next to their respective keys, in hexadecimal notation. */
void print_tree(node *root) {

  node *n = NULL;
  int i = 0;
  int rank = 0;
  int new_rank = 0;

  if (root == NULL) {
    printf("Empty tree.\n");
    return;
  }
  queue = NULL;
  enqueue(root);
  while (queue != NULL) {
    n = dequeue();
    if (n->parent != NULL && n == n->parent->pointers[0]) {
      new_rank = path_to_root(root, n);
      if (new_rank != rank) {
        rank = new_rank;
        printf("\n");
      }
    }
    if (verbose_output)
      printf("(%x)", n);
    for (i = 0; i < n->num_keys; i++) {
      if (verbose_output)
        printf("%x ", n->pointers[i]);
      printf("%d ", n->keys[i]);
    }
    if (!n->is_leaf)
      for (i = 0; i <= n->num_keys; i++)
        enqueue((node *)n->pointers[i]);
    if (verbose_output) {
      if (n->is_leaf)
        printf("%x ", n->pointers[order - 1]);
      else
        printf("%x ", n->pointers[n->num_keys]);
    }
    printf("| ");
  }
  printf("\n");
}

/* Traces the path from the root to a leaf, searching by key.  Displays
 * information about the path if the verbose flag is set. Returns the leaf
 * containing the given key. */
node *find_leaf(node *root, int key, bool verbose) {

  int i = 0;
  node *c = root;
  if (c == NULL) {
    if (verbose)
      printf("Empty tree.\n");
    return c;
  }
  while (!c->is_leaf) {
    if (verbose) {
      printf("[");
      for (i = 0; i < c->num_keys - 1; i++)
        printf("%d ", c->keys[i]);
      printf("%d] ", c->keys[i]);
    }
    i = 0;
    while (i < c->num_keys) {
      if (key >= c->keys[i])
        i++;
      else
        break;
    }
    if (verbose)
      printf("%d ->\n", i);
    c = (node *)c->pointers[i];
  }
  if (verbose) {
    printf("Leaf [");
    for (i = 0; i < c->num_keys - 1; i++)
      printf("%d ", c->keys[i]);
    printf("%d] ->\n", c->keys[i]);
  }
  return c;
}

/* Finds and returns the record to which a key refers. */
record *find(node *root, int key, bool verbose) {

  int i = 0;
  node *c = find_leaf(root, key, verbose);
  if (c == NULL)
    return NULL;
  for (i = 0; i < c->num_keys; i++)
    if (c->keys[i] == key)
      break;
  if (i == c->num_keys)
    return NULL;
  else
    return (record *)c->pointers[i];
}

/* Finds the appropriate place to split a node that is too big into two. */
int cut(int length) {
  if (length % 2 == 0)
    return length / 2;
  else
    return length / 2 + 1;
}

//======================================================================================================================================================150
// INSERTION
//======================================================================================================================================================150

/* Creates a new record to hold the value to which a key refers. */
record *make_record(int value) {
  record *new_record = (record *)malloc(sizeof(record));
  if (new_record == NULL) {
    perror("Record creation.");
    exit(EXIT_FAILURE);
  } else {
    new_record->value = value;
  }
  return new_record;
}

/* Creates a new general node, which can be adapted to serve as either a leaf or
 * an internal node. */
node *make_node(void) {
  node *new_node;
  new_node = (node *)malloc(sizeof(node));
  if (new_node == NULL) {
    perror("Node creation.");
    exit(EXIT_FAILURE);
  }
  new_node->keys = (int *)malloc((order - 1) * sizeof(int));
  if (new_node->keys == NULL) {
    perror("New node keys array.");
    exit(EXIT_FAILURE);
  }
  new_node->pointers = (void **)malloc(order * sizeof(void *));
  if (new_node->pointers == NULL) {
    perror("New node pointers array.");
    exit(EXIT_FAILURE);
  }
  new_node->is_leaf = false;
  new_node->num_keys = 0;
  new_node->parent = NULL;
  new_node->next = NULL;
  return new_node;
}

/* Creates a new leaf by creating a node and then adapting it appropriately. */
node *make_leaf(void) {
  node *leaf = make_node();
  leaf->is_leaf = true;
  return leaf;
}

/* Helper function used in insert_into_parent to find the index of the parent's
 * pointer to the node to the left of the key to be inserted. */
int get_left_index(node *parent, node *left) {

  int left_index = 0;
  while (left_index <= parent->num_keys && parent->pointers[left_index] != left)
    left_index++;
  return left_index;
}

/* Inserts a new pointer to a record and its corresponding key into a leaf.
 * Returns the altered leaf. */
node *insert_into_leaf(node *leaf, int key, record *pointer) {

  int i, insertion_point;

  insertion_point = 0;
  while (insertion_point < leaf->num_keys && leaf->keys[insertion_point] < key)
    insertion_point++;

  for (i = leaf->num_keys; i > insertion_point; i--) {
    leaf->keys[i] = leaf->keys[i - 1];
    leaf->pointers[i] = leaf->pointers[i - 1];
  }
  leaf->keys[insertion_point] = key;
  leaf->pointers[insertion_point] = pointer;
  leaf->num_keys++;
  return leaf;
}

/* Inserts a new key and pointer to a new record into a leaf so as to exceed the
 * tree's order, causing the leaf to be split in half. */
node *insert_into_leaf_after_splitting(node *root, node *leaf, int key,
                                       record *pointer) {

  node *new_leaf;
  int *temp_keys;
  void **temp_pointers;
  int insertion_index, split, new_key, i, j;

  new_leaf = make_leaf();

  temp_keys = (int *)malloc(order * sizeof(int));
  if (temp_keys == NULL) {
    perror("Temporary keys array.");
    exit(EXIT_FAILURE);
  }

  temp_pointers = (void **)malloc(order * sizeof(void *));
  if (temp_pointers == NULL) {
    perror("Temporary pointers array.");
    exit(EXIT_FAILURE);
  }

  insertion_index = 0;
  while (leaf->keys[insertion_index] < key && insertion_index < order - 1)
    insertion_index++;

  for (i = 0, j = 0; i < leaf->num_keys; i++, j++) {
    if (j == insertion_index)
      j++;
    temp_keys[j] = leaf->keys[i];
    temp_pointers[j] = leaf->pointers[i];
  }

  temp_keys[insertion_index] = key;
  temp_pointers[insertion_index] = pointer;

  leaf->num_keys = 0;

  split = cut(order - 1);

  for (i = 0; i < split; i++) {
    leaf->pointers[i] = temp_pointers[i];
    leaf->keys[i] = temp_keys[i];
    leaf->num_keys++;
  }

  for (i = split, j = 0; i < order; i++, j++) {
    new_leaf->pointers[j] = temp_pointers[i];
    new_leaf->keys[j] = temp_keys[i];
    new_leaf->num_keys++;
  }

  free(temp_pointers);
  free(temp_keys);

  new_leaf->pointers[order - 1] = leaf->pointers[order - 1];
  leaf->pointers[order - 1] = new_leaf;

  for (i = leaf->num_keys; i < order - 1; i++)
    leaf->pointers[i] = NULL;
  for (i = new_leaf->num_keys; i < order - 1; i++)
    new_leaf->pointers[i] = NULL;

  new_leaf->parent = leaf->parent;
  new_key = new_leaf->keys[0];

  return insert_into_parent(root, leaf, new_key, new_leaf);
}

/* Inserts a new key and pointer to a node into a node into which these can fit
 * without violating the B+ tree properties. */
node *insert_into_node(node *root, node *n, int left_index, int key,
                       node *right) {

  int i;

  for (i = n->num_keys; i > left_index; i--) {
    n->pointers[i + 1] = n->pointers[i];
    n->keys[i] = n->keys[i - 1];
  }
  n->pointers[left_index + 1] = right;
  n->keys[left_index] = key;
  n->num_keys++;
  return root;
}

/* Inserts a new key and pointer to a node into a node, causing the node's size
 * to exceed the order, and causing the node to split into two. */
node *insert_into_node_after_splitting(node *root, node *old_node,
                                       int left_index, int key, node *right) {

  int i, j, split, k_prime;
  node *new_node, *child;
  int *temp_keys;
  node **temp_pointers;

  /* First create a temporary set of keys and pointers
   * to hold everything in order, including
   * the new key and pointer, inserted in their
   * correct places.
   * Then create a new node and copy half of the
   * keys and pointers to the old node and
   * the other half to the new.
   */

  temp_pointers = (node **)malloc((order + 1) * sizeof(node *));
  if (temp_pointers == NULL) {
    perror("Temporary pointers array for splitting nodes.");
    exit(EXIT_FAILURE);
  }
  temp_keys = (int *)malloc(order * sizeof(int));
  if (temp_keys == NULL) {
    perror("Temporary keys array for splitting nodes.");
    exit(EXIT_FAILURE);
  }

  for (i = 0, j = 0; i < old_node->num_keys + 1; i++, j++) {
    if (j == left_index + 1)
      j++;
    temp_pointers[j] = (node *)old_node->pointers[i];
  }

  for (i = 0, j = 0; i < old_node->num_keys; i++, j++) {
    if (j == left_index)
      j++;
    temp_keys[j] = old_node->keys[i];
  }

  temp_pointers[left_index + 1] = right;
  temp_keys[left_index] = key;

  /* Create the new node and copy
   * half the keys and pointers to the
   * old and half to the new.
   */
  split = cut(order);
  new_node = make_node();
  old_node->num_keys = 0;
  for (i = 0; i < split - 1; i++) {
    old_node->pointers[i] = temp_pointers[i];
    old_node->keys[i] = temp_keys[i];
    old_node->num_keys++;
  }
  old_node->pointers[i] = temp_pointers[i];
  k_prime = temp_keys[split - 1];
  for (++i, j = 0; i < order; i++, j++) {
    new_node->pointers[j] = temp_pointers[i];
    new_node->keys[j] = temp_keys[i];
    new_node->num_keys++;
  }
  new_node->pointers[j] = temp_pointers[i];
  free(temp_pointers);
  free(temp_keys);
  new_node->parent = old_node->parent;
  for (i = 0; i <= new_node->num_keys; i++) {
    child = (node *)new_node->pointers[i];
    child->parent = new_node;
  }

  /* Insert a new key into the parent of the two
   * nodes resulting from the split, with
   * the old node to the left and the new to the right.
   */

  return insert_into_parent(root, old_node, k_prime, new_node);
}

/* Inserts a new node (leaf or internal node) into the B+ tree. Returns the root
 * of the tree after insertion. */
node *insert_into_parent(node *root, node *left, int key, node *right) {

  int left_index;
  node *parent;

  parent = left->parent;

  /* Case: new root. */

  if (parent == NULL)
    return insert_into_new_root(left, key, right);

  /* Case: leaf or node. (Remainder of
   * function body.)
   */

  /* Find the parent's pointer to the left
   * node.
   */

  left_index = get_left_index(parent, left);

  /* Simple case: the new key fits into the node.
   */

  if (parent->num_keys < order - 1)
    return insert_into_node(root, parent, left_index, key, right);

  /* Harder case:  split a node in order
   * to preserve the B+ tree properties.
   */

  return insert_into_node_after_splitting(root, parent, left_index, key, right);
}

/* Creates a new root for two subtrees and inserts the appropriate key into the
 * new root. */
node *insert_into_new_root(node *left, int key, node *right) {

  node *root = make_node();
  root->keys[0] = key;
  root->pointers[0] = left;
  root->pointers[1] = right;
  root->num_keys++;
  root->parent = NULL;
  left->parent = root;
  right->parent = root;
  return root;
}

/* First insertion: start a new tree. */
node *start_new_tree(int key, record *pointer) {

  node *root = make_leaf();
  root->keys[0] = key;
  root->pointers[0] = pointer;
  root->pointers[order - 1] = NULL;
  root->parent = NULL;
  root->num_keys++;
  return root;
}

/* Master insertion function. Inserts a key and an associated value into the B+
 * tree, causing the tree to be adjusted however necessary to maintain the B+
 * tree properties. */
node *insert(node *root, int key, int value) {

  record *pointer;
  node *leaf;

  /* The current implementation ignores duplicates. */
  if (find(root, key, false) != NULL)
    return root;

  /* Create a new record for the value. */
  pointer = make_record(value);

  /* Case: the tree does not exist yet. Start a new tree. */
  if (root == NULL)
    return start_new_tree(key, pointer);

  /* Case: the tree already exists. (Rest of function body.) */
  leaf = find_leaf(root, key, false);

  /* Case: leaf has room for key and pointer. */
  if (leaf->num_keys < order - 1) {
    leaf = insert_into_leaf(leaf, key, pointer);
    return root;
  }

  /* Case:  leaf must be split. */
  return insert_into_leaf_after_splitting(root, leaf, key, pointer);
}

//======================================================================================================================================================150
// DELETION
//======================================================================================================================================================150

/* Utility function for deletion. Retrieves the index of a node's nearest
 * neighbor (sibling) to the left if one exists.  If not (the node is the
 * leftmost child), returns -1 to signify this special case. */
int get_neighbor_index(node *n) {

  int i;

  /* Return the index of the key to the left
   * of the pointer in the parent pointing
   * to n.
   * If n is the leftmost child, this means
   * return -1.
   */
  for (i = 0; i <= n->parent->num_keys; i++)
    if (n->parent->pointers[i] == n)
      return i - 1;

  // Error state.
  printf("Search for nonexistent pointer to node in parent.\n");
  // printf("Node:  %#x\n", (unsigned int)n);
  exit(EXIT_FAILURE);
}

/*   */
node *remove_entry_from_node(node *n, int key, node *pointer) {

  int i, num_pointers;

  // Remove the key and shift other keys accordingly.
  i = 0;
  while (n->keys[i] != key)
    i++;
  for (++i; i < n->num_keys; i++)
    n->keys[i - 1] = n->keys[i];

  // Remove the pointer and shift other pointers accordingly.
  // First determine number of pointers.
  num_pointers = n->is_leaf ? n->num_keys : n->num_keys + 1;
  i = 0;
  while (n->pointers[i] != pointer)
    i++;
  for (++i; i < num_pointers; i++)
    n->pointers[i - 1] = n->pointers[i];

  // One key fewer.
  n->num_keys--;

  // Set the other pointers to NULL for tidiness.
  // A leaf uses the last pointer to point to the next leaf.
  if (n->is_leaf)
    for (i = n->num_keys; i < order - 1; i++)
      n->pointers[i] = NULL;
  else
    for (i = n->num_keys + 1; i < order; i++)
      n->pointers[i] = NULL;

  return n;
}

/*   */
node *adjust_root(node *root) {

  node *new_root;

  /* Case: nonempty root.
   * Key and pointer have already been deleted,
   * so nothing to be done.
   */

  if (root->num_keys > 0)
    return root;

  /* Case: empty root.
   */

  // If it has a child, promote
  // the first (only) child
  // as the new root.

  if (!root->is_leaf) {
    new_root = (node *)root->pointers[0];
    new_root->parent = NULL;
  }

  // If it is a leaf (has no children),
  // then the whole tree is empty.

  else
    new_root = NULL;

  free(root->keys);
  free(root->pointers);
  free(root);

  return new_root;
}

/* Coalesces a node that has become too small after deletion with a neighboring
 * node that can accept the additional entries without exceeding the maximum. */
node *coalesce_nodes(node *root, node *n, node *neighbor, int neighbor_index,
                     int k_prime) {

  int i, j, neighbor_insertion_index, n_start, n_end, new_k_prime;
  node *tmp;
  bool split;

  /* Swap neighbor with node if node is on the
   * extreme left and neighbor is to its right.
   */

  if (neighbor_index == -1) {
    tmp = n;
    n = neighbor;
    neighbor = tmp;
  }

  /* Starting point in the neighbor for copying
   * keys and pointers from n.
   * Recall that n and neighbor have swapped places
   * in the special case of n being a leftmost child.
   */

  neighbor_insertion_index = neighbor->num_keys;

  /*
   * Nonleaf nodes may sometimes need to remain split,
   * if the insertion of k_prime would cause the resulting
   * single coalesced node to exceed the limit order - 1.
   * The variable split is always false for leaf nodes
   * and only sometimes set to true for nonleaf nodes.
   */

  split = false;

  /* Case:  nonleaf node.
   * Append k_prime and the following pointer.
   * If there is room in the neighbor, append
   * all pointers and keys from the neighbor.
   * Otherwise, append only cut(order) - 2 keys and
   * cut(order) - 1 pointers.
   */

  if (!n->is_leaf) {

    /* Append k_prime.
     */

    neighbor->keys[neighbor_insertion_index] = k_prime;
    neighbor->num_keys++;

    /* Case (default):  there is room for all of n's keys and pointers
     * in the neighbor after appending k_prime.
     */

    n_end = n->num_keys;

    /* Case (special): k cannot fit with all the other keys and pointers
     * into one coalesced node.
     */
    n_start = 0; // Only used in this special case.
    if (n->num_keys + neighbor->num_keys >= order) {
      split = true;
      n_end = cut(order) - 2;
    }

    for (i = neighbor_insertion_index + 1, j = 0; j < n_end; i++, j++) {
      neighbor->keys[i] = n->keys[j];
      neighbor->pointers[i] = n->pointers[j];
      neighbor->num_keys++;
      n->num_keys--;
      n_start++;
    }

    /* The number of pointers is always
     * one more than the number of keys.
     */

    neighbor->pointers[i] = n->pointers[j];

    /* If the nodes are still split, remove the first key from
     * n.
     */
    if (split) {
      new_k_prime = n->keys[n_start];
      for (i = 0, j = n_start + 1; i < n->num_keys; i++, j++) {
        n->keys[i] = n->keys[j];
        n->pointers[i] = n->pointers[j];
      }
      n->pointers[i] = n->pointers[j];
      n->num_keys--;
    }

    /* All children must now point up to the same parent.
     */

    for (i = 0; i < neighbor->num_keys + 1; i++) {
      tmp = (node *)neighbor->pointers[i];
      tmp->parent = neighbor;
    }
  }

  /* In a leaf, append the keys and pointers of
   * n to the neighbor.
   * Set the neighbor's last pointer to point to
   * what had been n's right neighbor.
   */

  else {
    for (i = neighbor_insertion_index, j = 0; j < n->num_keys; i++, j++) {
      neighbor->keys[i] = n->keys[j];
      neighbor->pointers[i] = n->pointers[j];
      neighbor->num_keys++;
    }
    neighbor->pointers[order - 1] = n->pointers[order - 1];
  }

  if (!split) {
    root = delete_entry(root, n->parent, k_prime, n);
    free(n->keys);
    free(n->pointers);
    free(n);
  } else
    for (i = 0; i < n->parent->num_keys; i++)
      if (n->parent->pointers[i + 1] == n) {
        n->parent->keys[i] = new_k_prime;
        break;
      }

  return root;
}

/* Redistributes entries between two nodes when one has become too small after
 * deletion but its neighbor is too big to append the small node's entries
 * without exceeding the maximum */
node *redistribute_nodes(node *root, node *n, node *neighbor,
                         int neighbor_index, int k_prime_index, int k_prime) {

  int i;
  node *tmp;

  /* Case: n has a neighbor to the left.
   * Pull the neighbor's last key-pointer pair over
   * from the neighbor's right end to n's left end.
   */

  if (neighbor_index != -1) {
    if (!n->is_leaf)
      n->pointers[n->num_keys + 1] = n->pointers[n->num_keys];
    for (i = n->num_keys; i > 0; i--) {
      n->keys[i] = n->keys[i - 1];
      n->pointers[i] = n->pointers[i - 1];
    }
    if (!n->is_leaf) {
      n->pointers[0] = neighbor->pointers[neighbor->num_keys];
      tmp = (node *)n->pointers[0];
      tmp->parent = n;
      neighbor->pointers[neighbor->num_keys] = NULL;
      n->keys[0] = k_prime;
      n->parent->keys[k_prime_index] = neighbor->keys[neighbor->num_keys - 1];
    } else {
      n->pointers[0] = neighbor->pointers[neighbor->num_keys - 1];
      neighbor->pointers[neighbor->num_keys - 1] = NULL;
      n->keys[0] = neighbor->keys[neighbor->num_keys - 1];
      n->parent->keys[k_prime_index] = n->keys[0];
    }
  }

  /* Case: n is the leftmost child.
   * Take a key-pointer pair from the neighbor to the right.
   * Move the neighbor's leftmost key-pointer pair
   * to n's rightmost position.
   */

  else {
    if (n->is_leaf) {
      n->keys[n->num_keys] = neighbor->keys[0];
      n->pointers[n->num_keys] = neighbor->pointers[0];
      n->parent->keys[k_prime_index] = neighbor->keys[1];
    } else {
      n->keys[n->num_keys] = k_prime;
      n->pointers[n->num_keys + 1] = neighbor->pointers[0];
      tmp = (node *)n->pointers[n->num_keys + 1];
      tmp->parent = n;
      n->parent->keys[k_prime_index] = neighbor->keys[0];
    }
    for (i = 0; i < neighbor->num_keys; i++) {
      neighbor->keys[i] = neighbor->keys[i + 1];
      neighbor->pointers[i] = neighbor->pointers[i + 1];
    }
    if (!n->is_leaf)
      neighbor->pointers[i] = neighbor->pointers[i + 1];
  }

  /* n now has one more key and one more pointer;
   * the neighbor has one fewer of each.
   */

  n->num_keys++;
  neighbor->num_keys--;

  return root;
}

/* Deletes an entry from the B+ tree. Removes the record and its key and pointer
 * from the leaf, and then makes all appropriate changes to preserve the B+ tree
 * properties. */
node *delete_entry(node *root, node *n, int key, void *pointer) {

  int min_keys;
  node *neighbor;
  int neighbor_index;
  int k_prime_index, k_prime;
  int capacity;

  // Remove key and pointer from node.

  n = remove_entry_from_node(n, key, (node *)pointer);

  /* Case:  deletion from the root.
   */

  if (n == root)
    return adjust_root(root);

  /* Case:  deletion from a node below the root.
   * (Rest of function body.)
   */

  /* Determine minimum allowable size of node,
   * to be preserved after deletion.
   */

  min_keys = n->is_leaf ? cut(order - 1) : cut(order) - 1;

  /* Case:  node stays at or above minimum.
   * (The simple case.)
   */

  if (n->num_keys >= min_keys)
    return root;

  /* Case:  node falls below minimum.
   * Either coalescence or redistribution
   * is needed.
   */

  /* Find the appropriate neighbor node with which
   * to coalesce.
   * Also find the key (k_prime) in the parent
   * between the pointer to node n and the pointer
   * to the neighbor.
   */

  neighbor_index = get_neighbor_index(n);
  k_prime_index = neighbor_index == -1 ? 0 : neighbor_index;
  k_prime = n->parent->keys[k_prime_index];
  neighbor = neighbor_index == -1 ? (node *)n->parent->pointers[1]
                                  : (node *)n->parent->pointers[neighbor_index];

  capacity = n->is_leaf ? order : order - 1;

  /* Coalescence. */

  if (neighbor->num_keys + n->num_keys < capacity)
    return coalesce_nodes(root, n, neighbor, neighbor_index, k_prime);

  /* Redistribution. */

  else
    return redistribute_nodes(root, n, neighbor, neighbor_index, k_prime_index,
                              k_prime);
}

/* Master deletion function. */
node *deleteVal(node *root, int key) {

  node *key_leaf;
  record *key_record;

  key_record = find(root, key, false);
  key_leaf = find_leaf(root, key, false);
  if (key_record != NULL && key_leaf != NULL) {
    free(key_record);
    root = delete_entry(root, key_leaf, key, key_record);
  }
  return root;
}

/*   */
void destroy_tree_nodes(node *root) {
  int i;
  if (root->is_leaf)
    for (i = 0; i < root->num_keys; i++)
      free(root->pointers[i]);
  else
    for (i = 0; i < root->num_keys + 1; i++)
      destroy_tree_nodes((node *)root->pointers[i]);
  free(root->pointers);
  free(root->keys);
  free(root);
}

/*   */
node *destroy_tree(node *root) {
  destroy_tree_nodes(root);
  return NULL;
}

//======================================================================================================================================================150
//	END
//======================================================================================================================================================150

//========================================================================================================================================================================================================200
//	MAIN FUNCTION
//========================================================================================================================================================================================================200

int main(int argc, char **argv) {

  printf("WG size of kernel 1 & 2  = %d \n", DEFAULT_ORDER);

  // ------------------------------------------------------------60
  // figure out and display whether 32-bit or 64-bit architecture
  // ------------------------------------------------------------60

  // if(sizeof(int *)==8){
  // printf("64 bit machine\n");
  // }
  // else if(sizeof(int *)==4){
  // printf("32 bit machine\n");
  // }

  // ------------------------------------------------------------60
  // set GPU
  // ------------------------------------------------------------60

  int device = 0;
  cudaSetDevice(device);
  printf("Selecting device %d\n", device);

  // ------------------------------------------------------------60
  // read inputs
  // ------------------------------------------------------------60

  // assing default values
  int cur_arg;
  int arch_arg;
  arch_arg = 0;
  int cores_arg;
  cores_arg = 1;
  char *input_file = NULL;
  char *command_file = NULL;
  char *output = "output.txt";
  FILE *pFile;

  // go through arguments
  for (cur_arg = 1; cur_arg < argc; cur_arg++) {
    // check if -file
    if (strcmp(argv[cur_arg], "file") == 0) {
      // check if value provided
      if (argc >= cur_arg + 1) {
        input_file = argv[cur_arg + 1];
        cur_arg = cur_arg + 1;
        // value is not a number
      }
      // value not provided
      else {
        printf("ERROR: Missing value to -file parameter\n");
        return -1;
      }
    } else if (strcmp(argv[cur_arg], "command") == 0) {
      // check if value provided
      if (argc >= cur_arg + 1) {
        command_file = argv[cur_arg + 1];
        cur_arg = cur_arg + 1;
        // value is not a number
      }
      // value not provided
      else {
        printf("ERROR: Missing value to command parameter\n");
        return -1;
      }
    }
  }
  // Print configuration
  if ((input_file == NULL) || (command_file == NULL))
    printf("Usage: ./b+tree file input_file command command_list\n");

  // For debug
  printf("Input File: %s \n", input_file);
  printf("Command File: %s \n", command_file);

  FILE *commandFile;
  long lSize;
  char *commandBuffer;
  size_t result;

  commandFile = fopen(command_file, "rb");
  if (commandFile == NULL) {
    fputs("Command File error", stderr);
    exit(1);
  }

  // obtain file size:
  fseek(commandFile, 0, SEEK_END);
  lSize = ftell(commandFile);
  rewind(commandFile);

  // allocate memory to contain the whole file:
  commandBuffer = (char *)malloc(sizeof(char) * lSize);
  if (commandBuffer == NULL) {
    fputs("Command Buffer memory error", stderr);
    exit(2);
  }

  // copy the file into the buffer:
  result = fread(commandBuffer, 1, lSize, commandFile);
  if (result != lSize) {
    fputs("Command file reading error", stderr);
    exit(3);
  }

  /* the whole file is now loaded in the memory buffer. */

  // terminate
  fclose(commandFile);

  // For Debug
  char *sPointer = commandBuffer;
  printf("Command Buffer: \n");
  printf("%s", commandBuffer);
  //

  pFile = fopen(output, "w+");
  if (pFile == NULL)
    fputs("Fail to open %s !\n", output);
  fprintf(pFile, "******starting******\n");
  fclose(pFile);

  // ------------------------------------------------------------60
  // general variables
  // ------------------------------------------------------------60

  FILE *file_pointer;
  node *root;
  root = NULL;
  record *r;
  int input;
  char instruction;
  order = DEFAULT_ORDER;
  verbose_output = false;

  // usage_1();
  // usage_2();

  // ------------------------------------------------------------60
  // get input from file, if file provided
  // ------------------------------------------------------------60

  if (input_file != NULL) {

    printf("Getting input from file %s...\n", input_file);

    // open input file
    file_pointer = fopen(input_file, "r");
    if (file_pointer == NULL) {
      perror("Failure to open input file.");
      exit(EXIT_FAILURE);
    }

    // get # of numbers in the file
    fscanf(file_pointer, "%d\n", &input);
    size = input;

    // save all numbers
    while (!feof(file_pointer)) {
      fscanf(file_pointer, "%d\n", &input);
      root = insert(root, input, input);
    }

    // close file
    fclose(file_pointer);
    // print_tree(root);
    // printf("Height of tree = %d\n", height(root));

  } else {
    printf("ERROR: Argument -file missing\n");
    return 0;
  }

  // ------------------------------------------------------------60
  // get tree statistics
  // ------------------------------------------------------------60

  printf("Transforming data to a GPU suitable structure...\n");
  long mem_used = transform_to_cuda(root, 0);
  maxheight = height(root);
  long rootLoc = (long)knodes - (long)mem;

  // ------------------------------------------------------------60
  // process commands
  // ------------------------------------------------------------60
  char *commandPointer = commandBuffer;

  printf("Waiting for command\n");
  printf("> ");
  while (sscanf(commandPointer, "%c", &instruction) != EOF) {
    commandPointer++;
    switch (instruction) {
      // ----------------------------------------40
      // Insert
      // ----------------------------------------40

    case 'i': {
      scanf("%d", &input);
      while (getchar() != (int)'\n')
        ;
      root = insert(root, input, input);
      print_tree(root);
      break;
    }

      // ----------------------------------------40
      // n/a
      // ----------------------------------------40

    case 'f': {
    }

      // ----------------------------------------40
      // find
      // ----------------------------------------40

    case 'p': {
      scanf("%d", &input);
      while (getchar() != (int)'\n')
        ;
      r = find(root, input, instruction == 'p');
      if (r == NULL)
        printf("Record not found under key %d.\n", input);
      else
        printf("Record found: %d\n", r->value);
      break;
    }

      // ----------------------------------------40
      // delete value
      // ----------------------------------------40

    case 'd': {
      scanf("%d", &input);
      while (getchar() != (int)'\n')
        ;
      root = (node *)deleteVal(root, input);
      print_tree(root);
      break;
    }

      // ----------------------------------------40
      // destroy tree
      // ----------------------------------------40

    case 'x': {
      while (getchar() != (int)'\n')
        ;
      root = destroy_tree(root);
      print_tree(root);
      break;
    }

      // ----------------------------------------40
      // print leaves
      // ----------------------------------------40

    case 'l': {
      while (getchar() != (int)'\n')
        ;
      print_leaves(root);
      break;
    }

      // ----------------------------------------40
      // print tree
      // ----------------------------------------40

    case 't': {
      while (getchar() != (int)'\n')
        ;
      print_tree(root);
      break;
    }

      // ----------------------------------------40
      // toggle verbose output
      // ----------------------------------------40

    case 'v': {
      while (getchar() != (int)'\n')
        ;
      verbose_output = !verbose_output;
      break;
    }

      // ----------------------------------------40
      // quit
      // ----------------------------------------40

    case 'q': {
      while (getchar() != (int)'\n')
        ;
      return EXIT_SUCCESS;
    }

      // ----------------------------------------40
      // [GPU] find K (initK, findK)
      // ----------------------------------------40

    case 'k': {

      // get # of queries from user
      int count;
      sscanf(commandPointer, "%d", &count);
      while (*commandPointer != 32 && commandPointer != '\n')
        commandPointer++;

      printf("\n ******command: k count=%d \n", count);
      if (count > 65535) {
        printf("ERROR: Number of requested querries should be 65,535 at most. "
               "(limited by # of CUDA blocks)\n");
        exit(0);
      }

      // INPUT: records CPU allocation (setting pointer in mem variable)
      record *records = (record *)mem;
      long records_elem = (long)rootLoc / sizeof(record);
      long records_mem = (long)rootLoc;
      printf("records_elem=%d, records_unit_mem=%d, records_mem=%d\n",
             (int)records_elem, (int)sizeof(record), (int)records_mem);

      // INPUT: knodes CPU allocation (setting pointer in mem variable)
      knode *knodes = (knode *)((long)mem + (long)rootLoc);
      long knodes_elem = ((long)(mem_used) - (long)rootLoc) / sizeof(knode);
      long knodes_mem = (long)(mem_used) - (long)rootLoc;
      printf("knodes_elem=%d, knodes_unit_mem=%d, knodes_mem=%d\n",
             (int)knodes_elem, (int)sizeof(knode), (int)knodes_mem);

      // INPUT: currKnode CPU allocation
      long *currKnode;
      currKnode = (long *)malloc(count * sizeof(long));
      // INPUT: offset CPU initialization
      memset(currKnode, 0, count * sizeof(long));

      // INPUT: offset CPU allocation
      long *offset;
      offset = (long *)malloc(count * sizeof(long));
      // INPUT: offset CPU initialization
      memset(offset, 0, count * sizeof(long));

      // INPUT: keys CPU allocation
      int *keys;
      keys = (int *)malloc(count * sizeof(int));
      // INPUT: keys CPU initialization
      int i;
      for (i = 0; i < count; i++) {
        keys[i] = (rand() / (float)RAND_MAX) * size;
      }

      // OUTPUT: ans CPU allocation
      record *ans = (record *)malloc(sizeof(record) * count);
      // OUTPUT: ans CPU initialization
      for (i = 0; i < count; i++) {
        ans[i].value = -1;
      }

      // CUDA kernel
      kernel_gpu_cuda_wrapper(records, records_mem, knodes, knodes_elem,
                              knodes_mem,

                              order, maxheight, count,

                              currKnode, offset, keys, ans);

      /* printf("ans: \n"); */
      /* for(i = 0; i < count; i++){ */
      /*   printf("%d    ",ans[i].value); */
      /* } */

      /* printf(" \n"); */

      pFile = fopen(output, "aw+");
      if (pFile == NULL) {
        fputs("Fail to open %s !\n", output);
      }

      fprintf(pFile, "\n ******command: k count=%d \n", count);
      for (i = 0; i < count; i++) {
        fprintf(pFile, "%d    %d\n", i, ans[i].value);
      }
      fprintf(pFile, " \n");
      fclose(pFile);

      // free memory
      free(currKnode);
      free(offset);
      free(keys);
      free(ans);

      // break out of case
      break;
    }

      // ----------------------------------------40
      // find range
      // ----------------------------------------40

    case 'r': {
      int start, end;
      scanf("%d", &start);
      scanf("%d", &end);
      if (start > end) {
        input = start;
        start = end;
        end = input;
      }
      printf("For range %d to %d, ", start, end);
      list_t *ansList;
      ansList = findRange(root, start, end);
      printf("%d records found\n", list_get_length(ansList));
      // list_iterator_t iter;
      free(ansList);
      break;
    }

      // ----------------------------------------40
      // [GPU] find Range K (initK, findRangeK)
      // ----------------------------------------40

    case 'j': {

      // get # of queries from user
      int count;
      sscanf(commandPointer, "%d", &count);
      while (*commandPointer != 32 && commandPointer != '\n')
        commandPointer++;

      int rSize;
      sscanf(commandPointer, "%d", &rSize);
      while (*commandPointer != 32 && commandPointer != '\n')
        commandPointer++;

      printf("\n******command: j count=%d, rSize=%d \n", count, rSize);
      if (rSize > size || rSize < 0) {
        printf("Search range size is larger than data set size %d.\n",
               (int)size);
        exit(0);
      }

      // INPUT: knodes CPU allocation (setting pointer in mem variable)
      knode *knodes = (knode *)((long)mem + (long)rootLoc);
      long knodes_elem = ((long)(mem_used) - (long)rootLoc) / sizeof(knode);
      long knodes_mem = (long)(mem_used) - (long)rootLoc;
      printf("knodes_elem=%d, knodes_unit_mem=%d, knodes_mem=%d\n",
             (int)knodes_elem, (int)sizeof(knode), (int)knodes_mem);

      // INPUT: currKnode CPU allocation
      long *currKnode;
      currKnode = (long *)malloc(count * sizeof(long));
      // INPUT: offset CPU initialization
      memset(currKnode, 0, count * sizeof(long));

      // INPUT: offset CPU allocation
      long *offset;
      offset = (long *)malloc(count * sizeof(long));
      // INPUT: offset CPU initialization
      memset(offset, 0, count * sizeof(long));

      // INPUT: lastKnode CPU allocation
      long *lastKnode;
      lastKnode = (long *)malloc(count * sizeof(long));
      // INPUT: offset CPU initialization
      memset(lastKnode, 0, count * sizeof(long));

      // INPUT: offset_2 CPU allocation
      long *offset_2;
      offset_2 = (long *)malloc(count * sizeof(long));
      // INPUT: offset CPU initialization
      memset(offset_2, 0, count * sizeof(long));

      // INPUT: start, end CPU allocation
      int *start;
      start = (int *)malloc(count * sizeof(int));
      int *end;
      end = (int *)malloc(count * sizeof(int));
      // INPUT: start, end CPU initialization
      int i;
      for (i = 0; i < count; i++) {
        start[i] = (rand() / (float)RAND_MAX) * size;
        end[i] = start[i] + rSize;
        if (end[i] >= size) {
          start[i] = start[i] - (end[i] - size);
          end[i] = size - 1;
        }
      }

      // INPUT: recstart, reclenght CPU allocation
      int *recstart;
      recstart = (int *)malloc(count * sizeof(int));
      int *reclength;
      reclength = (int *)malloc(count * sizeof(int));
      // OUTPUT: ans CPU initialization
      for (i = 0; i < count; i++) {
        recstart[i] = 0;
        reclength[i] = 0;
      }

      // CUDA kernel
      kernel_gpu_cuda_wrapper_2(knodes, knodes_elem, knodes_mem,

                                order, maxheight, count,

                                currKnode, offset, lastKnode, offset_2, start,
                                end, recstart, reclength);

      pFile = fopen(output, "aw+");
      if (pFile == NULL) {
        fputs("Fail to open %s !\n", output);
      }

      fprintf(pFile, "\n******command: j count=%d, rSize=%d \n", count, rSize);
      for (i = 0; i < count; i++) {
        fprintf(pFile, "%d    %d    %d\n", i, recstart[i], reclength[i]);
      }
      fprintf(pFile, " \n");
      fclose(pFile);

      // free memory
      free(currKnode);
      free(offset);
      free(lastKnode);
      free(offset_2);
      free(start);
      free(end);
      free(recstart);
      free(reclength);

      // break out of case
      break;
    }

      // ----------------------------------------40
      // default
      // ----------------------------------------40

    default: {

      // usage_2();
      break;
    }
    }
    printf("> ");
  }
  printf("\n");

  // ------------------------------------------------------------60
  // free remaining memory and exit
  // ------------------------------------------------------------60

  free(mem);
  return EXIT_SUCCESS;
}

//========================================================================================================================================================================================================200
//	END
//========================================================================================================================================================================================================200

// # ifdef __cplusplus
// }
// # endif