int main(int argc, char * argv[])
{
char * pathname;
if (argc >= 2)
{
pathname = argv[1];
}
else
pathname = getenv("PWD");
mkfifo(FIFONAME, 0664);
int fd = open(FIFONAME, O_RDONLY | O_NONBLOCK);
int i = recursive_search(pathname, FIFONAME,0,0);
if (i < 0)
{
perror("Error on recursive search");
return -1;
}
FILE * stream = fdopen(fd, "r");
char * buf = malloc(5);
size_t buf_size = 5;
size_t read;
int count = 0;
int average = 0;
int temp = 0;
while ( (read = getline(&buf, &buf_size, stream)) != -1)
{
temp = atoi(buf);
average+=temp;
count++;
}
average /= count;
printf("\n\n");
printf("Average length of file names: %D\n", average);
printf("Starting printing of file names above average...\n");
i = recursive_search(pathname, FIFONAME, 1, average);
if (i < 0)
{
perror("Error on printing recursion");
return -1;
}
free(buf);
}
/* The main function. This is where the function result is computed */
long long go_isa(UDF_INIT *initid, UDF_ARGS *args,
char *is_null, char *error)
{
long dnaLength= args->lengths[0];
const char *child=args->args[0];
const char *parent=args->args[0];
char name1[MAX_TERM_LENGTH];
char name2[MAX_TERM_LENGTH];
TermDBPtr termdb=(TermDBPtr)initid->ptr;
int index;
*is_null=0;
if (args->args[0]==NULL || args->args[1]==NULL
|| args->lengths[0]>=MAX_TERM_LENGTH
|| args->lengths[1]>=MAX_TERM_LENGTH
) /* Null argument */
{
*is_null=1;
return -1;
}
strncpy(name1,args->args[0],args->lengths[0]);
name1[args->lengths[0]]=0;
strncpy(name2,args->args[1],args->lengths[1]);
name2[args->lengths[1]]=0;
index=termdb_findIndexByName(termdb,name1);
if(index==-1)
{
return 0;
}
return recursive_search(termdb,index,name2,0);
}
bool recursive_search(int value, int *array, int start, int end)
{
// Found needle
if (value == array[(start+end)] / 2)
return true;
while (start <= end)
{
// Declare middle variable
int middle = (start + end) / 2;
// Recursively search left/right portion of the array
if (value > array[middle])
return recursive_search(value, array, middle + 1, end);
else
return recursive_search(value, array, start, middle - 1);
}
// Unable to locate value
return false;
}
static int recursive_search(const TermDBPtr db,int index, const char* parent,int depth)
{
int rez=0;
int start=index;
int parent_idx=0;
if(start<0 || start>=db->n_terms) return 0;
if(strcmp(db->terms[index].child,parent)==0) return 1;
while(index < db->n_terms)
{
if(strcmp(db->terms[index].child,db->terms[start].child)!=0) break;
if(strcmp(db->terms[index].parent,parent)==0) return 1;
parent_idx= termdb_findIndexByName(db,db->terms[index].parent);
rez= recursive_search(db,parent_idx,parent,depth+1);
if(rez==1 ) return 1;
++index;
}
return 0;
}
int task_execute(oph_operator_struct * handle)
{
if (!handle || !handle->operator_handle) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Null Handle\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_NULL_OPERATOR_HANDLE);
return OPH_ANALYTICS_OPERATOR_NULL_OPERATOR_HANDLE;
}
//Only master process has to continue
if (handle->proc_rank != 0)
return OPH_ANALYTICS_OPERATOR_SUCCESS;
int folderid;
char *abs_path = NULL;
char *filters = NULL;
int *max_lengths = NULL;
int max_lengths_size;
int permission = 0;
ophidiadb *oDB = &((OPH_SEARCH_operator_handle *) handle->operator_handle)->oDB;
if (!strcasecmp(((OPH_SEARCH_operator_handle *) handle->operator_handle)->path, OPH_FRAMEWORK_FS_DEFAULT_PATH)) {
if (oph_odb_fs_path_parsing(".", ((OPH_SEARCH_operator_handle *) handle->operator_handle)->cwd, &folderid, &abs_path, oDB)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Unable to parse path\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_PATH_PARSING_ERROR);
return OPH_ANALYTICS_OPERATOR_UTILITY_ERROR;
}
} else {
if (oph_odb_fs_path_parsing(((OPH_SEARCH_operator_handle *) handle->operator_handle)->path, ((OPH_SEARCH_operator_handle *) handle->operator_handle)->cwd, &folderid, &abs_path, oDB)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Unable to parse path '%s/%s'\n", ((OPH_SEARCH_operator_handle *) handle->operator_handle)->cwd,
((OPH_SEARCH_operator_handle *) handle->operator_handle)->path);
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_PATH_PARSING_ERROR);
return OPH_ANALYTICS_OPERATOR_UTILITY_ERROR;
}
}
if ((oph_odb_fs_check_folder_session(folderid, ((OPH_SEARCH_operator_handle *) handle->operator_handle)->sessionid, oDB, &permission)) || !permission) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Path %s not allowed\n", abs_path);
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_PATH_NOT_ALLOWED_ERROR, abs_path);
if (abs_path) {
free(abs_path);
abs_path = NULL;
}
return OPH_ANALYTICS_OPERATOR_BAD_PARAMETER;
}
// Change folder_to_be_printed in user format
if (abs_path) {
char old_abs_path[1 + strlen(abs_path)];
strcpy(old_abs_path, abs_path);
free(abs_path);
abs_path = NULL;
if (oph_pid_drop_session_prefix(old_abs_path, ((OPH_SEARCH_operator_handle *) handle->operator_handle)->sessionid, &abs_path)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Folder conversion error\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, "Folder conversion error\n");
if (abs_path) {
free(abs_path);
abs_path = NULL;
}
return OPH_ANALYTICS_OPERATOR_BAD_PARAMETER;
}
}
if (get_filters_string
(((OPH_SEARCH_operator_handle *) handle->operator_handle)->container_filter, ((OPH_SEARCH_operator_handle *) handle->operator_handle)->container_filter_num,
((OPH_SEARCH_operator_handle *) handle->operator_handle)->metadata_key_filter, ((OPH_SEARCH_operator_handle *) handle->operator_handle)->metadata_key_filter_num,
((OPH_SEARCH_operator_handle *) handle->operator_handle)->metadata_value_filter, ((OPH_SEARCH_operator_handle *) handle->operator_handle)->metadata_value_filter_num, &filters)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Unable to parse filters\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_FILTERS_PARSING_ERROR);
if (abs_path) {
free(abs_path);
abs_path = NULL;
}
return OPH_ANALYTICS_OPERATOR_UTILITY_ERROR;
}
if (recursive_get_max_lengths(strlen(abs_path), folderid, filters, oDB, &max_lengths, &max_lengths_size, NULL, 1)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Search error\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_SEARCH_ERROR);
if (abs_path) {
free(abs_path);
abs_path = NULL;
}
if (filters) {
free(filters);
filters = NULL;
}
return OPH_ANALYTICS_OPERATOR_UTILITY_ERROR;
}
if (recursive_search
(abs_path, folderid, filters, oDB, max_lengths, max_lengths_size, NULL, NULL, 1, handle->operator_json,
oph_json_is_objkey_printable(((OPH_SEARCH_operator_handle *) handle->operator_handle)->objkeys, ((OPH_SEARCH_operator_handle *) handle->operator_handle)->objkeys_num,
OPH_JSON_OBJKEY_SEARCH))) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Search error\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_SEARCH_ERROR);
if (abs_path) {
free(abs_path);
abs_path = NULL;
}
if (filters) {
free(filters);
filters = NULL;
}
if (max_lengths) {
free(max_lengths);
max_lengths = NULL;
}
return OPH_ANALYTICS_OPERATOR_UTILITY_ERROR;
}
if (abs_path) {
free(abs_path);
abs_path = NULL;
}
if (filters) {
free(filters);
filters = NULL;
}
if (max_lengths) {
free(max_lengths);
max_lengths = NULL;
}
return OPH_ANALYTICS_OPERATOR_SUCCESS;
}
int recursive_search(const char *folder_abs_path, int folderid, const char *filters, ophidiadb * oDB, int *max_lengths, int max_lengths_size, char *query, char *path, int is_start,
oph_json * oper_json, int is_objkey_printable)
{
if (!oDB) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Null input parameter\n");
return OPH_ODB_NULL_PARAM;
}
if (oph_odb_check_connection_to_ophidiadb(oDB)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Unable to reconnect to OphidiaDB.\n");
return OPH_ODB_MYSQL_ERROR;
}
MYSQL_RES *res;
MYSQL_FIELD *fields;
MYSQL_ROW row;
int i, j, num_fields;
char *buffer;
char *buffer2;
if (is_start) {
buffer = malloc(MYSQL_BUFLEN);
if (!buffer) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Error allocating memory for query\n");
return OPH_ANALYTICS_OPERATOR_MEMORY_ERR;
}
buffer2 = malloc(MYSQL_BUFLEN);
if (!buffer2) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Error allocating memory for path\n");
free(buffer);
return OPH_ANALYTICS_OPERATOR_MEMORY_ERR;
}
} else {
buffer = query;
buffer2 = path;
}
snprintf(buffer, MYSQL_BUFLEN, MYSQL_QUERY_OPH_SEARCH_READ_INSTANCES, folderid, filters);
if (mysql_query(oDB->conn, buffer)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "MySQL query error: %s\n", mysql_error(oDB->conn));
free(buffer);
free(buffer2);
return OPH_ANALYTICS_OPERATOR_MYSQL_ERROR;
}
res = mysql_store_result(oDB->conn);
fields = mysql_fetch_fields(res);
num_fields = mysql_num_fields(res) - 1;
if (is_start) {
//print header
printf("+");
for (i = 0; i < max_lengths_size; i++) {
printf("-");
for (j = 0; j < max_lengths[i]; j++) {
printf("-");
}
printf("-+");
}
printf("\n");
printf("|");
for (i = 0; i < max_lengths_size; i++) {
printf(" ");
printf("%-*s", max_lengths[i], fields[i].name);
printf(" |");
}
printf("\n");
printf("+");
for (i = 0; i < max_lengths_size; i++) {
printf("-");
for (j = 0; j < max_lengths[i]; j++) {
printf("-");
}
printf("-+");
}
printf("\n");
if (is_objkey_printable) {
char **jsonkeys = NULL;
char **fieldtypes = NULL;
int iii, jjj;
jsonkeys = (char **) malloc(sizeof(char *) * num_fields);
if (!jsonkeys) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Error allocating memory\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_MEMORY_ERROR_INPUT, "keys");
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_MEMORY_ERR;
}
for (jjj = 0; jjj < num_fields; ++jjj) {
jsonkeys[jjj] = strdup(fields[jjj + 1].name ? fields[jjj + 1].name : "");
if (!jsonkeys[jjj]) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Error allocating memory\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_MEMORY_ERROR_INPUT, "key");
for (iii = 0; iii < jjj; iii++)
if (jsonkeys[iii])
free(jsonkeys[iii]);
if (jsonkeys)
free(jsonkeys);
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_MEMORY_ERR;
}
}
fieldtypes = (char **) malloc(sizeof(char *) * num_fields);
if (!fieldtypes) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Error allocating memory\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_MEMORY_ERROR_INPUT, "fieldtypes");
for (iii = 0; iii < num_fields; iii++)
if (jsonkeys[iii])
free(jsonkeys[iii]);
if (jsonkeys)
free(jsonkeys);
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_MEMORY_ERR;
}
for (jjj = 0; jjj < num_fields; ++jjj) {
fieldtypes[jjj] = strdup(OPH_JSON_STRING);
if (!fieldtypes[jjj]) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Error allocating memory\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_MEMORY_ERROR_INPUT, "fieldtype");
for (iii = 0; iii < num_fields; iii++)
if (jsonkeys[iii])
free(jsonkeys[iii]);
if (jsonkeys)
free(jsonkeys);
for (iii = 0; iii < jjj; iii++)
if (fieldtypes[iii])
free(fieldtypes[iii]);
if (fieldtypes)
free(fieldtypes);
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_MEMORY_ERR;
}
}
if (oph_json_add_grid(oper_json, OPH_JSON_OBJKEY_SEARCH, "Searching results", NULL, jsonkeys, num_fields, fieldtypes, num_fields)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "ADD GRID error\n");
logging(LOG_WARNING, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, "ADD GRID error\n");
for (iii = 0; iii < num_fields; iii++)
if (jsonkeys[iii])
free(jsonkeys[iii]);
if (jsonkeys)
free(jsonkeys);
for (iii = 0; iii < num_fields; iii++)
if (fieldtypes[iii])
free(fieldtypes[iii]);
if (fieldtypes)
free(fieldtypes);
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_UTILITY_ERROR;
}
for (iii = 0; iii < num_fields; iii++)
if (jsonkeys[iii])
free(jsonkeys[iii]);
if (jsonkeys)
free(jsonkeys);
for (iii = 0; iii < num_fields; iii++)
if (fieldtypes[iii])
free(fieldtypes[iii]);
if (fieldtypes)
free(fieldtypes);
}
}
//print each ROW
while ((row = mysql_fetch_row(res))) {
printf("|");
for (i = 0; i < max_lengths_size; i++) {
printf(" ");
if (!strcasecmp(fields[i].name, "Container")) {
if (folder_abs_path[strlen(folder_abs_path) - 1] == '/') {
snprintf(buffer2, MYSQL_BUFLEN, "%s%s", folder_abs_path, row[i]);
} else {
snprintf(buffer2, MYSQL_BUFLEN, "%s/%s", folder_abs_path, row[i]);
}
printf("%-*s", max_lengths[i], buffer2);
} else {
printf("%-*s", max_lengths[i], row[i]);
}
printf(" |");
}
printf("\n");
if (is_objkey_printable) {
char **jsonvalues = NULL;
int iii, jjj;
jsonvalues = (char **) calloc(num_fields, sizeof(char *));
if (!jsonvalues) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Error allocating memory\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_MEMORY_ERROR_INPUT, "values");
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_MEMORY_ERR;
}
for (jjj = 0; jjj < num_fields; ++jjj) {
if (jjj)
jsonvalues[jjj] = strdup(row[1 + jjj] ? row[1 + jjj] : "");
else {
char *tmp_uri = NULL, *pid = NULL;
if (oph_pid_get_uri(&tmp_uri)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Error allocating memory\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_MEMORY_ERROR_INPUT, "PID");
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_MEMORY_ERR;
}
if (oph_pid_create_pid(tmp_uri, (int) strtol(row[0], NULL, 10), (int) strtol(row[1], NULL, 10), &pid)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Unable to create PID string\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_MEMORY_ERROR_INPUT, "PID");
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_MEMORY_ERR;
}
if (tmp_uri)
free(tmp_uri);
jsonvalues[jjj] = strdup(pid ? pid : "");
}
if (!jsonvalues[jjj]) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Error allocating memory\n");
logging(LOG_ERROR, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, OPH_LOG_OPH_SEARCH_MEMORY_ERROR_INPUT, "value");
for (iii = 0; iii < jjj; iii++)
if (jsonvalues[iii])
free(jsonvalues[iii]);
if (jsonvalues)
free(jsonvalues);
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_MEMORY_ERR;
}
}
if (oph_json_add_grid_row(oper_json, OPH_JSON_OBJKEY_SEARCH, jsonvalues)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "ADD GRID ROW error\n");
logging(LOG_WARNING, __FILE__, __LINE__, OPH_GENERIC_CONTAINER_ID, "ADD GRID ROW error\n");
for (iii = 0; iii < num_fields; iii++)
if (jsonvalues[iii])
free(jsonvalues[iii]);
if (jsonvalues)
free(jsonvalues);
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_UTILITY_ERROR;
}
for (iii = 0; iii < num_fields; iii++)
if (jsonvalues[iii])
free(jsonvalues[iii]);
if (jsonvalues)
free(jsonvalues);
}
}
mysql_free_result(res);
//recursive step
snprintf(buffer, MYSQL_BUFLEN, MYSQL_QUERY_OPH_SEARCH_READ_SUBFOLDERS, folderid);
if (mysql_query(oDB->conn, buffer)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "MySQL query error: %s\n", mysql_error(oDB->conn));
free(buffer);
free(buffer2);
return OPH_ANALYTICS_OPERATOR_MYSQL_ERROR;
}
res = mysql_store_result(oDB->conn);
while ((row = mysql_fetch_row(res))) {
if (folder_abs_path[strlen(folder_abs_path) - 1] == '/') {
snprintf(buffer2, MYSQL_BUFLEN, "%s%s/", folder_abs_path, row[1]);
} else {
snprintf(buffer2, MYSQL_BUFLEN, "%s/%s/", folder_abs_path, row[1]);
}
char *subfolder_path = strdup(buffer2);
if (!subfolder_path) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Error allocating memory for subfolder path\n");
free(buffer);
free(buffer2);
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_MEMORY_ERR;
}
if (recursive_search(subfolder_path, (int) strtol(row[0], NULL, 10), filters, oDB, max_lengths, max_lengths_size, buffer, buffer2, 0, oper_json, is_objkey_printable)) {
pmesg(LOG_ERROR, __FILE__, __LINE__, "Recursive step error\n");
free(buffer);
free(buffer2);
free(subfolder_path);
mysql_free_result(res);
return OPH_ANALYTICS_OPERATOR_UTILITY_ERROR;
}
free(subfolder_path);
}
mysql_free_result(res);
if (is_start) {
//print footer
printf("+");
for (i = 0; i < max_lengths_size; i++) {
printf("-");
for (j = 0; j < max_lengths[i]; j++) {
printf("-");
}
printf("-+");
}
printf("\n");
if (buffer) {
free(buffer);
buffer = NULL;
}
if (buffer2) {
free(buffer2);
buffer2 = NULL;
}
}
return OPH_ANALYTICS_OPERATOR_SUCCESS;
}
int main(void) {
int i;
node *t1, *t2, *t3;
/* recursive_insert() */
printf("=== Tesing Insert Recursive ===\n");
t1 = NULL;
int tree_values[10] = {5, 8, 3, 6, 1, 4, 9, 0, 7, 2};
for (i=0; i<10; i++) {
recursive_insert(&t1,tree_values[i]);
}
printf("=== Inorder Traversal ===\n");
print_inorder_traverse(t1);
printf("\n");
printf("=== PreOrder Traversal ===\n");
print_preorder_traverse(t1);
printf("\n");
printf("=== PostOrder Traversal ===\n");
print_postorder_traverse(t1);
printf("\n");
node *elem;
printf("=== Recursive Search ===\n");
elem = recursive_search(t1, 5);
printf("%d\n", elem->value);
printf("%d\n", elem->left->value);
printf("%d\n", elem->right->value);
printf("\n");
printf("=== Copy Tree ===\n");
t2=copy(t1);
print_inorder_traverse(t1);
printf("\n");
print_inorder_traverse(t2);
printf("\n");
printf("=== Depth ===\n");
int _d = depth(t1);
printf("%d\n", _d);
printf("\n");
printf("=== Num Nodes ===\n");
int _n = num_nodes(t1);
printf("%d\n", _n);
printf("\n");
printf("=== Destroy ===\n");
destroy(&t1);
print_inorder_traverse(t1);
printf("\n");
printf("=== Is Identical ===\n");
t1=NULL;
t2=NULL;
for (i=0; i<10; i++) {
recursive_insert(&t1,tree_values[i]);
recursive_insert(&t2,tree_values[i]);
}
int identical = is_identical(t1, t2);
if (identical)
printf("%s\n", "Trees are identical");
else
printf("%s\n", "Trees are not identical");
printf("\n");
printf("=== Num of Leaves ===\n");
int leaves = num_leaves(t1);
printf("%d\n", leaves);
printf("\n");
}
