Commit 274b25eb authored by Yoni Fogel's avatar Yoni Fogel

refs #5081 Replace all usage:

BOOL->bool
FALSE->false
TRUE->true
u_int*_t->uint*_t

Also poisoned all of the variables

git-svn-id: file:///svn/mysql/tokudb-engine/tokudb-engine@46156 c7de825b-a66e-492c-adef-691d508d4ae1
parent 16f359b7
......@@ -79,7 +79,7 @@ static void share_key_file_unlock(TOKUDB_SHARE * share)
//
// This offset is calculated starting from AFTER the NULL bytes
//
static inline u_int32_t get_fixed_field_size(KEY_AND_COL_INFO* kc_info, TABLE_SHARE* table_share, uint keynr) {
static inline uint32_t get_fixed_field_size(KEY_AND_COL_INFO* kc_info, TABLE_SHARE* table_share, uint keynr) {
uint offset = 0;
for (uint i = 0; i < table_share->fields; i++) {
if (kc_info->field_lengths[i] && !bitmap_is_set(&kc_info->key_filters[keynr],i)) {
......@@ -90,7 +90,7 @@ static inline u_int32_t get_fixed_field_size(KEY_AND_COL_INFO* kc_info, TABLE_SH
}
static inline u_int32_t get_len_of_offsets(KEY_AND_COL_INFO* kc_info, TABLE_SHARE* table_share, uint keynr) {
static inline uint32_t get_len_of_offsets(KEY_AND_COL_INFO* kc_info, TABLE_SHARE* table_share, uint keynr) {
uint len = 0;
for (uint i = 0; i < table_share->fields; i++) {
if (kc_info->length_bytes[i] && !bitmap_is_set(&kc_info->key_filters[keynr],i)) {
......@@ -121,9 +121,9 @@ static int allocate_key_and_col_info ( TABLE_SHARE* table_share, KEY_AND_COL_INF
//
// create the field lengths
//
kc_info->field_lengths = (u_int16_t *)my_malloc(table_share->fields*sizeof(u_int16_t), MYF(MY_WME | MY_ZEROFILL));
kc_info->field_lengths = (uint16_t *)my_malloc(table_share->fields*sizeof(uint16_t), MYF(MY_WME | MY_ZEROFILL));
kc_info->length_bytes= (uchar *)my_malloc(table_share->fields, MYF(MY_WME | MY_ZEROFILL));
kc_info->blob_fields= (u_int32_t *)my_malloc(table_share->fields*sizeof(u_int32_t), MYF(MY_WME | MY_ZEROFILL));
kc_info->blob_fields= (uint32_t *)my_malloc(table_share->fields*sizeof(uint32_t), MYF(MY_WME | MY_ZEROFILL));
if (kc_info->field_lengths == NULL ||
kc_info->length_bytes == NULL ||
......@@ -636,7 +636,7 @@ static inline HA_TOKU_ISO_LEVEL tx_to_toku_iso(ulong tx_isolation) {
}
}
static inline u_int32_t toku_iso_to_txn_flag (HA_TOKU_ISO_LEVEL lvl) {
static inline uint32_t toku_iso_to_txn_flag (HA_TOKU_ISO_LEVEL lvl) {
if (lvl == hatoku_iso_read_uncommitted) {
return DB_READ_UNCOMMITTED;
}
......@@ -724,7 +724,7 @@ void set_key_filter(MY_BITMAP* key_filter, KEY* key, TABLE* table, bool get_offs
static inline uchar* pack_fixed_field(
uchar* to_tokudb,
const uchar* from_mysql,
u_int32_t num_bytes
uint32_t num_bytes
)
{
switch (num_bytes) {
......@@ -753,7 +753,7 @@ static inline uchar* pack_fixed_field(
static inline const uchar* unpack_fixed_field(
uchar* to_mysql,
const uchar* from_tokudb,
u_int32_t num_bytes
uint32_t num_bytes
)
{
switch (num_bytes) {
......@@ -784,15 +784,15 @@ static inline uchar* write_var_field(
uchar* to_tokudb_data, // location where data is going to be written
uchar* to_tokudb_offset_start, //location where offset starts, IS THIS A BAD NAME????
const uchar * data, // the data to write
u_int32_t data_length, // length of data to write
u_int32_t offset_bytes // number of offset bytes
uint32_t data_length, // length of data to write
uint32_t offset_bytes // number of offset bytes
)
{
memcpy(to_tokudb_data, data, data_length);
//
// for offset, we pack the offset where the data ENDS!
//
u_int32_t offset = to_tokudb_data + data_length - to_tokudb_offset_start;
uint32_t offset = to_tokudb_data + data_length - to_tokudb_offset_start;
switch(offset_bytes) {
case (1):
to_tokudb_offset_ptr[0] = (uchar)offset;
......@@ -807,12 +807,12 @@ static inline uchar* write_var_field(
return to_tokudb_data + data_length;
}
static inline u_int32_t get_var_data_length(
static inline uint32_t get_var_data_length(
const uchar * from_mysql,
u_int32_t mysql_length_bytes
uint32_t mysql_length_bytes
)
{
u_int32_t data_length;
uint32_t data_length;
switch(mysql_length_bytes) {
case(1):
data_length = from_mysql[0];
......@@ -832,8 +832,8 @@ static inline uchar* pack_var_field(
uchar* to_tokudb_data, // pointer to where tokudb data should be written
uchar* to_tokudb_offset_start, //location where data starts, IS THIS A BAD NAME????
const uchar * from_mysql, // mysql data
u_int32_t mysql_length_bytes, //number of bytes used to store length in from_mysql
u_int32_t offset_bytes //number of offset_bytes used in tokudb row
uint32_t mysql_length_bytes, //number of bytes used to store length in from_mysql
uint32_t offset_bytes //number of offset_bytes used in tokudb row
)
{
uint data_length = get_var_data_length(from_mysql, mysql_length_bytes);
......@@ -850,8 +850,8 @@ static inline uchar* pack_var_field(
static inline void unpack_var_field(
uchar* to_mysql,
const uchar* from_tokudb_data,
u_int32_t from_tokudb_data_len,
u_int32_t mysql_length_bytes
uint32_t from_tokudb_data_len,
uint32_t mysql_length_bytes
)
{
//
......@@ -880,14 +880,14 @@ static uchar* pack_toku_field_blob(
Field* field
)
{
u_int32_t len_bytes = field->row_pack_length();
u_int32_t length = 0;
uint32_t len_bytes = field->row_pack_length();
uint32_t length = 0;
uchar* data_ptr = NULL;
memcpy(to_tokudb, from_mysql, len_bytes);
switch (len_bytes) {
case (1):
length = (u_int32_t)(*from_mysql);
length = (uint32_t)(*from_mysql);
break;
case (2):
length = uint2korr(from_mysql);
......@@ -1067,13 +1067,13 @@ static inline int tokudb_generate_row(
DB* curr_db = dest_db;
uchar* row_desc = NULL;
u_int32_t desc_size;
uint32_t desc_size;
uchar* buff = NULL;
u_int32_t max_key_len = 0;
uint32_t max_key_len = 0;
row_desc = (uchar *)curr_db->descriptor->dbt.data;
row_desc += (*(u_int32_t *)row_desc);
desc_size = (*(u_int32_t *)row_desc) - 4;
row_desc += (*(uint32_t *)row_desc);
desc_size = (*(uint32_t *)row_desc) - 4;
row_desc += 4;
if (is_key_pk(row_desc, desc_size)) {
......@@ -1141,7 +1141,7 @@ static inline int tokudb_generate_row(
}
row_desc += desc_size;
desc_size = (*(u_int32_t *)row_desc) - 4;
desc_size = (*(uint32_t *)row_desc) - 4;
row_desc += 4;
if (dest_val != NULL) {
if (!is_key_clustering(row_desc, desc_size) || src_val->size == 0) {
......@@ -1257,7 +1257,7 @@ ha_tokudb::ha_tokudb(handlerton * hton, TABLE_SHARE * table_arg):handler(hton, t
abort_loader = false;
memset(&lc, 0, sizeof(lc));
lock.type = TL_IGNORE;
for (u_int32_t i = 0; i < MAX_KEY+1; i++) {
for (uint32_t i = 0; i < MAX_KEY+1; i++) {
mult_put_flags[i] = 0;
mult_del_flags[i] = DB_DELETE_ANY;
mult_dbt_flags[i] = DB_DBT_REALLOC;
......@@ -1307,7 +1307,7 @@ static int open_status_dictionary(DB** ptr, const char* name, DB_TXN* txn) {
int error;
char* newname = NULL;
uint open_mode = DB_THREAD;
u_int32_t pagesize = 0;
uint32_t pagesize = 0;
newname = (char *)my_malloc(
get_max_dict_name_path_length(name),
MYF(MY_WME)
......@@ -1461,8 +1461,8 @@ static int initialize_col_pack_info(KEY_AND_COL_INFO* kc_info, TABLE_SHARE* tabl
goto exit;
}
{
u_int32_t curr_fixed_offset = 0;
u_int32_t curr_var_index = 0;
uint32_t curr_fixed_offset = 0;
uint32_t curr_var_index = 0;
for (uint j = 0; j < table_share->fields; j++) {
COL_PACK_INFO* curr = &kc_info->cp_info[keynr][j];
//
......@@ -1511,8 +1511,8 @@ static void reset_key_and_col_info(KEY_AND_COL_INFO *kc_info, uint keynr) {
static int initialize_key_and_col_info(TABLE_SHARE* table_share, TABLE* table, KEY_AND_COL_INFO* kc_info, uint hidden_primary_key, uint primary_key) {
int error = 0;
u_int32_t curr_blob_field_index = 0;
u_int32_t max_var_bytes = 0;
uint32_t curr_blob_field_index = 0;
uint32_t max_var_bytes = 0;
//
// fill in the field lengths. 0 means it is a variable sized field length
// fill in length_bytes, 0 means it is fixed or blob
......@@ -1529,7 +1529,7 @@ static int initialize_key_and_col_info(TABLE_SHARE* table_share, TABLE* table, K
case toku_type_fixstring:
pack_length = field->pack_length();
assert(pack_length < 1<<16);
kc_info->field_lengths[i] = (u_int16_t)pack_length;
kc_info->field_lengths[i] = (uint16_t)pack_length;
kc_info->length_bytes[i] = 0;
break;
case toku_type_blob:
......@@ -1643,7 +1643,7 @@ int ha_tokudb::initialize_share(
)
{
int error = 0;
u_int64_t num_rows = 0;
uint64_t num_rows = 0;
bool table_exists;
DB_TXN* txn = NULL;
bool do_commit = false;
......@@ -1734,7 +1734,7 @@ int ha_tokudb::initialize_share(
// We need to set the ref_length to start at 5, to account for
// the "infinity byte" in keys, and for placing the DBT size in the first four bytes
//
ref_length = sizeof(u_int32_t) + sizeof(uchar);
ref_length = sizeof(uint32_t) + sizeof(uchar);
KEY_PART_INFO *key_part = table->key_info[primary_key].key_part;
KEY_PART_INFO *end = key_part + table->key_info[primary_key].key_parts;
for (; key_part != end; key_part++) {
......@@ -1811,7 +1811,7 @@ int ha_tokudb::open(const char *name, int mode, uint test_if_locked) {
primary_key = table_share->keys;
key_used_on_scan = MAX_KEY;
hidden_primary_key = TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH;
ref_length = TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH + sizeof(u_int32_t);
ref_length = TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH + sizeof(uint32_t);
}
else {
key_used_on_scan = primary_key;
......@@ -1829,8 +1829,8 @@ int ha_tokudb::open(const char *name, int mode, uint test_if_locked) {
&prelocked_left_range, max_key_length,
&prelocked_right_range, max_key_length,
&primary_key_buff, (hidden_primary_key ? 0 : max_key_length),
&fixed_cols_for_query, table_share->fields*sizeof(u_int32_t),
&var_cols_for_query, table_share->fields*sizeof(u_int32_t),
&fixed_cols_for_query, table_share->fields*sizeof(uint32_t),
&var_cols_for_query, table_share->fields*sizeof(uint32_t),
NullS
);
if (alloc_ptr == NULL) {
......@@ -1859,11 +1859,11 @@ int ha_tokudb::open(const char *name, int mode, uint test_if_locked) {
goto exit;
}
for (u_int32_t i = 0; i < sizeof(mult_key_dbt)/sizeof(mult_key_dbt[0]); i++) {
for (uint32_t i = 0; i < sizeof(mult_key_dbt)/sizeof(mult_key_dbt[0]); i++) {
mult_key_dbt[i].flags = DB_DBT_REALLOC;
}
for (u_int32_t i = 0; i < curr_num_DBs; i++) {
for (uint32_t i = 0; i < curr_num_DBs; i++) {
mult_rec_dbt[i].flags = DB_DBT_REALLOC;
}
......@@ -1929,7 +1929,7 @@ int ha_tokudb::open(const char *name, int mode, uint test_if_locked) {
// 0 on success
// error otherwise
//
int ha_tokudb::estimate_num_rows(DB* db, u_int64_t* num_rows, DB_TXN* txn) {
int ha_tokudb::estimate_num_rows(DB* db, uint64_t* num_rows, DB_TXN* txn) {
int error = ENOSYS;
DBC* crsr = NULL;
bool do_commit = false;
......@@ -2193,13 +2193,13 @@ int ha_tokudb::__close(int mutex_is_locked) {
my_free(blob_buff, MYF(MY_ALLOW_ZERO_PTR));
my_free(alloc_ptr, MYF(MY_ALLOW_ZERO_PTR));
my_free(range_query_buff, MYF(MY_ALLOW_ZERO_PTR));
for (u_int32_t i = 0; i < sizeof(mult_rec_dbt)/sizeof(mult_rec_dbt[0]); i++) {
for (uint32_t i = 0; i < sizeof(mult_rec_dbt)/sizeof(mult_rec_dbt[0]); i++) {
if (mult_rec_dbt[i].flags == DB_DBT_REALLOC &&
mult_rec_dbt[i].data != NULL) {
free(mult_rec_dbt[i].data);
}
}
for (u_int32_t i = 0; i < sizeof(mult_key_dbt)/sizeof(mult_key_dbt[0]); i++) {
for (uint32_t i = 0; i < sizeof(mult_key_dbt)/sizeof(mult_key_dbt[0]); i++) {
if (mult_key_dbt[i].flags == DB_DBT_REALLOC &&
mult_key_dbt[i].data != NULL) {
free(mult_key_dbt[i].data);
......@@ -2366,7 +2366,7 @@ int ha_tokudb::pack_old_row_for_update(
int ha_tokudb::unpack_blobs(
uchar* record,
const uchar* from_tokudb_blob,
u_int32_t num_bytes,
uint32_t num_bytes,
bool check_bitmap
)
{
......@@ -2390,13 +2390,13 @@ int ha_tokudb::unpack_blobs(
memcpy(blob_buff, from_tokudb_blob, num_bytes);
buff= blob_buff;
for (uint i = 0; i < share->kc_info.num_blobs; i++) {
u_int32_t curr_field_index = share->kc_info.blob_fields[i];
uint32_t curr_field_index = share->kc_info.blob_fields[i];
bool skip = check_bitmap ?
!(bitmap_is_set(table->read_set,curr_field_index) ||
bitmap_is_set(table->write_set,curr_field_index)) :
false;
Field* field = table->field[curr_field_index];
u_int32_t len_bytes = field->row_pack_length();
uint32_t len_bytes = field->row_pack_length();
buff = unpack_toku_field_blob(
record + field_offset(field, table),
buff,
......@@ -2432,7 +2432,7 @@ int ha_tokudb::unpack_row(
const uchar* fixed_field_ptr = (const uchar *) row->data;
const uchar* var_field_offset_ptr = NULL;
const uchar* var_field_data_ptr = NULL;
u_int32_t data_end_offset = 0;
uint32_t data_end_offset = 0;
memcpy(record, fixed_field_ptr, table_share->null_bytes);
fixed_field_ptr += table_share->null_bytes;
......@@ -2446,7 +2446,7 @@ int ha_tokudb::unpack_row(
unpack_key(record,key,index);
}
u_int32_t last_offset = 0;
uint32_t last_offset = 0;
//
// we have two methods of unpacking, one if we need to unpack the entire row
// the second if we unpack a subset of the entire row
......@@ -2499,7 +2499,7 @@ int ha_tokudb::unpack_row(
error = unpack_blobs(
record,
var_field_data_ptr,
row->size - (u_int32_t)(var_field_data_ptr - (const uchar *)row->data),
row->size - (uint32_t)(var_field_data_ptr - (const uchar *)row->data),
false
);
if (error) {
......@@ -2514,7 +2514,7 @@ int ha_tokudb::unpack_row(
//
// first the fixed fields
//
for (u_int32_t i = 0; i < num_fixed_cols_for_query; i++) {
for (uint32_t i = 0; i < num_fixed_cols_for_query; i++) {
uint field_index = fixed_cols_for_query[i];
Field* field = table->field[field_index];
unpack_fixed_field(
......@@ -2528,12 +2528,12 @@ int ha_tokudb::unpack_row(
// now the var fields
// here, we do NOT modify var_field_data_ptr or var_field_offset_ptr
//
for (u_int32_t i = 0; i < num_var_cols_for_query; i++) {
for (uint32_t i = 0; i < num_var_cols_for_query; i++) {
uint field_index = var_cols_for_query[i];
Field* field = table->field[field_index];
u_int32_t var_field_index = share->kc_info.cp_info[index][field_index].col_pack_val;
u_int32_t data_start_offset;
u_int32_t field_len;
uint32_t var_field_index = share->kc_info.cp_info[index][field_index].col_pack_val;
uint32_t data_start_offset;
uint32_t field_len;
get_var_field_info(
&field_len,
......@@ -2566,7 +2566,7 @@ int ha_tokudb::unpack_row(
error = unpack_blobs(
record,
var_field_data_ptr,
row->size - (u_int32_t)(var_field_data_ptr - (const uchar *)row->data),
row->size - (uint32_t)(var_field_data_ptr - (const uchar *)row->data),
true
);
if (error) {
......@@ -2579,7 +2579,7 @@ int ha_tokudb::unpack_row(
return error;
}
u_int32_t ha_tokudb::place_key_into_mysql_buff(
uint32_t ha_tokudb::place_key_into_mysql_buff(
KEY* key_info,
uchar * record,
uchar* data
......@@ -2626,7 +2626,7 @@ u_int32_t ha_tokudb::place_key_into_mysql_buff(
// unpacking a key of
//
void ha_tokudb::unpack_key(uchar * record, DBT const *key, uint index) {
u_int32_t bytes_read;
uint32_t bytes_read;
uchar *pos = (uchar *) key->data + 1;
bytes_read = place_key_into_mysql_buff(
&table->key_info[index],
......@@ -2645,7 +2645,7 @@ void ha_tokudb::unpack_key(uchar * record, DBT const *key, uint index) {
}
}
u_int32_t ha_tokudb::place_key_into_dbt_buff(
uint32_t ha_tokudb::place_key_into_dbt_buff(
KEY* key_info,
uchar * buff,
const uchar * record,
......@@ -2721,7 +2721,7 @@ DBT* ha_tokudb::create_dbt_key_from_key(
int key_length
)
{
u_int32_t size = 0;
uint32_t size = 0;
uchar* tmp_buff = buff;
my_bitmap_map *old_map = dbug_tmp_use_all_columns(table, table->write_set);
......@@ -3065,12 +3065,12 @@ ha_rows ha_tokudb::estimate_rows_upper_bound() {
int ha_tokudb::cmp_ref(const uchar * ref1, const uchar * ref2) {
int ret_val = 0;
ret_val = tokudb_compare_two_keys(
ref1 + sizeof(u_int32_t),
*(u_int32_t *)ref1,
ref2 + sizeof(u_int32_t),
*(u_int32_t *)ref2,
ref1 + sizeof(uint32_t),
*(uint32_t *)ref1,
ref2 + sizeof(uint32_t),
*(uint32_t *)ref2,
(uchar *)share->file->descriptor->dbt.data + 4,
*(u_int32_t *)share->file->descriptor->dbt.data - 4,
*(uint32_t *)share->file->descriptor->dbt.data - 4,
false
);
return ret_val;
......@@ -3173,7 +3173,7 @@ void ha_tokudb::start_bulk_insert(ha_rows rows) {
if (!thd_test_options(thd, OPTION_RELAXED_UNIQUE_CHECKS) && !hidden_primary_key) {
mult_put_flags[primary_key] = DB_NOOVERWRITE;
}
u_int32_t loader_flags = (get_load_save_space(thd)) ?
uint32_t loader_flags = (get_load_save_space(thd)) ?
LOADER_USE_PUTS : 0;
int error = db_env->create_loader(
......@@ -3307,7 +3307,7 @@ int ha_tokudb::is_index_unique(bool* is_unique, DB_TXN* txn, DB* db, KEY* key_in
DBC* tmp_cursor1 = NULL;
DBC* tmp_cursor2 = NULL;
DBT key1, key2, val, packed_key1, packed_key2;
u_int64_t cnt = 0;
uint64_t cnt = 0;
char status_msg[MAX_ALIAS_NAME + 200]; //buffer of 200 should be a good upper bound.
THD* thd = ha_thd();
memset(&key1, 0, sizeof(key1));
......@@ -3594,9 +3594,9 @@ void ha_tokudb::test_row_packing(uchar* record, DBT* pk_key, DBT* pk_val) {
tmp_pk_val.size = pk_val->size;
for (uint keynr = 0; keynr < table_share->keys; keynr++) {
u_int32_t tmp_num_bytes = 0;
uint32_t tmp_num_bytes = 0;
uchar* row_desc = NULL;
u_int32_t desc_size = 0;
uint32_t desc_size = 0;
if (keynr == primary_key) {
continue;
......@@ -3608,8 +3608,8 @@ void ha_tokudb::test_row_packing(uchar* record, DBT* pk_key, DBT* pk_val) {
// TEST
//
row_desc = (uchar *)share->key_file[keynr]->descriptor->dbt.data;
row_desc += (*(u_int32_t *)row_desc);
desc_size = (*(u_int32_t *)row_desc) - 4;
row_desc += (*(uint32_t *)row_desc);
desc_size = (*(uint32_t *)row_desc) - 4;
row_desc += 4;
tmp_num_bytes = pack_key_from_desc(
key_buff3,
......@@ -3632,9 +3632,9 @@ void ha_tokudb::test_row_packing(uchar* record, DBT* pk_key, DBT* pk_val) {
tmp_buff = (uchar *)my_malloc(alloced_rec_buff_length,MYF(MY_WME));
assert(tmp_buff);
row_desc = (uchar *)share->key_file[keynr]->descriptor->dbt.data;
row_desc += (*(u_int32_t *)row_desc);
row_desc += (*(u_int32_t *)row_desc);
desc_size = (*(u_int32_t *)row_desc) - 4;
row_desc += (*(uint32_t *)row_desc);
row_desc += (*(uint32_t *)row_desc);
desc_size = (*(uint32_t *)row_desc) - 4;
row_desc += 4;
tmp_num_bytes = pack_clustering_val_from_desc(
tmp_buff,
......@@ -3667,10 +3667,10 @@ void ha_tokudb::test_row_packing(uchar* record, DBT* pk_key, DBT* pk_val) {
void ha_tokudb::set_main_dict_put_flags(
THD* thd,
bool opt_eligible,
u_int32_t* put_flags
uint32_t* put_flags
)
{
u_int32_t old_prelock_flags = 0;
uint32_t old_prelock_flags = 0;
uint curr_num_DBs = table->s->keys + test(hidden_primary_key);
bool in_hot_index = share->num_DBs > curr_num_DBs;
bool using_ignore_flag_opt = do_ignore_flag_optimization(
......@@ -3713,7 +3713,7 @@ void ha_tokudb::set_main_dict_put_flags(
int ha_tokudb::insert_row_to_main_dictionary(uchar* record, DBT* pk_key, DBT* pk_val, DB_TXN* txn) {
int error = 0;
u_int32_t put_flags = mult_put_flags[primary_key];
uint32_t put_flags = mult_put_flags[primary_key];
THD *thd = ha_thd();
uint curr_num_DBs = table->s->keys + test(hidden_primary_key);
......@@ -4234,8 +4234,8 @@ int ha_tokudb::delete_row(const uchar * record) {
// and var_cols_for_query
//
void ha_tokudb::set_query_columns(uint keynr) {
u_int32_t curr_fixed_col_index = 0;
u_int32_t curr_var_col_index = 0;
uint32_t curr_fixed_col_index = 0;
uint32_t curr_var_col_index = 0;
read_key = false;
read_blobs = false;
//
......@@ -4699,7 +4699,7 @@ int ha_tokudb::index_read(uchar * buf, const uchar * key, uint key_len, enum ha_
DBT row;
DBT lookup_key;
int error = 0;
u_int32_t flags = 0;
uint32_t flags = 0;
THD* thd = ha_thd();
tokudb_trx_data* trx = (tokudb_trx_data *) thd_data_get(thd, tokudb_hton->slot);;
struct smart_dbt_info info;
......@@ -4801,7 +4801,7 @@ int ha_tokudb::read_data_from_range_query_buff(uchar* buf, bool need_val) {
memset((void *) &curr_key, 0, sizeof(curr_key));
// get key info
u_int32_t key_size = *(u_int32_t *)curr_pos;
uint32_t key_size = *(uint32_t *)curr_pos;
curr_pos += sizeof(key_size);
uchar* curr_key_buff = curr_pos;
curr_pos += key_size;
......@@ -4821,7 +4821,7 @@ int ha_tokudb::read_data_from_range_query_buff(uchar* buf, bool need_val) {
DBT curr_val;
memset((void *) &curr_val, 0, sizeof(curr_val));
uchar* curr_val_buff = NULL;
u_int32_t val_size = 0;
uint32_t val_size = 0;
// in this case, we don't have a val, we are simply extracting the pk
if (!need_val) {
curr_val.data = curr_val_buff;
......@@ -4834,7 +4834,7 @@ int ha_tokudb::read_data_from_range_query_buff(uchar* buf, bool need_val) {
// need to extract a val and place it into buf
if (unpack_entire_row) {
// get val info
val_size = *(u_int32_t *)curr_pos;
val_size = *(uint32_t *)curr_pos;
curr_pos += sizeof(val_size);
curr_val_buff = curr_pos;
curr_pos += val_size;
......@@ -4853,7 +4853,7 @@ int ha_tokudb::read_data_from_range_query_buff(uchar* buf, bool need_val) {
curr_pos += table_share->null_bytes;
// now the fixed sized rows
for (u_int32_t i = 0; i < num_fixed_cols_for_query; i++) {
for (uint32_t i = 0; i < num_fixed_cols_for_query; i++) {
uint field_index = fixed_cols_for_query[i];
Field* field = table->field[field_index];
unpack_fixed_field(
......@@ -4864,10 +4864,10 @@ int ha_tokudb::read_data_from_range_query_buff(uchar* buf, bool need_val) {
curr_pos += share->kc_info.field_lengths[field_index];
}
// now the variable sized rows
for (u_int32_t i = 0; i < num_var_cols_for_query; i++) {
for (uint32_t i = 0; i < num_var_cols_for_query; i++) {
uint field_index = var_cols_for_query[i];
Field* field = table->field[field_index];
u_int32_t field_len = *(u_int32_t *)curr_pos;
uint32_t field_len = *(uint32_t *)curr_pos;
curr_pos += sizeof(field_len);
unpack_var_field(
buf + field_offset(field, table),
......@@ -4879,7 +4879,7 @@ int ha_tokudb::read_data_from_range_query_buff(uchar* buf, bool need_val) {
}
// now the blobs
if (read_blobs) {
u_int32_t blob_size = *(u_int32_t *)curr_pos;
uint32_t blob_size = *(uint32_t *)curr_pos;
curr_pos += sizeof(blob_size);
error = unpack_blobs(
buf,
......@@ -4921,24 +4921,24 @@ int ha_tokudb::fill_range_query_buf(
//
// first put the value into range_query_buf
//
u_int32_t size_remaining = size_range_query_buff - bytes_used_in_range_query_buff;
u_int32_t size_needed;
u_int32_t user_defined_size = get_tokudb_read_buf_size(thd);
uint32_t size_remaining = size_range_query_buff - bytes_used_in_range_query_buff;
uint32_t size_needed;
uint32_t user_defined_size = get_tokudb_read_buf_size(thd);
uchar* curr_pos = NULL;
if (need_val) {
if (unpack_entire_row) {
size_needed = 2*sizeof(u_int32_t) + key->size + row->size;
size_needed = 2*sizeof(uint32_t) + key->size + row->size;
}
else {
// this is an upper bound
size_needed = sizeof(u_int32_t) + // size of key length
size_needed = sizeof(uint32_t) + // size of key length
key->size + row->size + //key and row
num_var_cols_for_query*(sizeof(u_int32_t)) + //lengths of varchars stored
sizeof(u_int32_t); //length of blobs
num_var_cols_for_query*(sizeof(uint32_t)) + //lengths of varchars stored
sizeof(uint32_t); //length of blobs
}
}
else {
size_needed = sizeof(u_int32_t) + key->size;
size_needed = sizeof(uint32_t) + key->size;
}
if (size_remaining < size_needed) {
range_query_buff = (uchar *)my_realloc(
......@@ -4958,14 +4958,14 @@ int ha_tokudb::fill_range_query_buf(
//
curr_pos = range_query_buff + bytes_used_in_range_query_buff;
*(u_int32_t *)curr_pos = key->size;
curr_pos += sizeof(u_int32_t);
*(uint32_t *)curr_pos = key->size;
curr_pos += sizeof(uint32_t);
memcpy(curr_pos, key->data, key->size);
curr_pos += key->size;
if (need_val) {
if (unpack_entire_row) {
*(u_int32_t *)curr_pos = row->size;
curr_pos += sizeof(u_int32_t);
*(uint32_t *)curr_pos = row->size;
curr_pos += sizeof(uint32_t);
memcpy(curr_pos, row->data, row->size);
curr_pos += row->size;
}
......@@ -4987,7 +4987,7 @@ int ha_tokudb::fill_range_query_buf(
//
// first the fixed fields
//
for (u_int32_t i = 0; i < num_fixed_cols_for_query; i++) {
for (uint32_t i = 0; i < num_fixed_cols_for_query; i++) {
uint field_index = fixed_cols_for_query[i];
memcpy(
curr_pos,
......@@ -5000,11 +5000,11 @@ int ha_tokudb::fill_range_query_buf(
//
// now the var fields
//
for (u_int32_t i = 0; i < num_var_cols_for_query; i++) {
for (uint32_t i = 0; i < num_var_cols_for_query; i++) {
uint field_index = var_cols_for_query[i];
u_int32_t var_field_index = share->kc_info.cp_info[active_index][field_index].col_pack_val;
u_int32_t data_start_offset;
u_int32_t field_len;
uint32_t var_field_index = share->kc_info.cp_info[active_index][field_index].col_pack_val;
uint32_t data_start_offset;
uint32_t field_len;
get_var_field_info(
&field_len,
......@@ -5020,8 +5020,8 @@ int ha_tokudb::fill_range_query_buf(
}
if (read_blobs) {
u_int32_t blob_offset = 0;
u_int32_t data_size = 0;
uint32_t blob_offset = 0;
uint32_t data_size = 0;
//
// now the blobs
//
......@@ -5031,7 +5031,7 @@ int ha_tokudb::fill_range_query_buf(
var_field_data_ptr,
share->kc_info.num_offset_bytes
);
data_size = row->size - blob_offset - (u_int32_t)(var_field_data_ptr - (const uchar *)row->data);
data_size = row->size - blob_offset - (uint32_t)(var_field_data_ptr - (const uchar *)row->data);
memcpy(curr_pos, &data_size, sizeof(data_size));
curr_pos += sizeof(data_size);
memcpy(curr_pos, var_field_data_ptr + blob_offset, data_size);
......@@ -5111,7 +5111,7 @@ int ha_tokudb::fill_range_query_buf(
int ha_tokudb::get_next(uchar* buf, int direction) {
int error = 0;
u_int32_t flags = SET_PRELOCK_FLAG(0);
uint32_t flags = SET_PRELOCK_FLAG(0);
THD* thd = ha_thd();
tokudb_trx_data* trx = (tokudb_trx_data *) thd_data_get(thd, tokudb_hton->slot);;
bool need_val;
......@@ -5244,7 +5244,7 @@ int ha_tokudb::index_first(uchar * buf) {
invalidate_bulk_fetch();
int error = 0;
struct smart_dbt_info info;
u_int32_t flags = SET_PRELOCK_FLAG(0);
uint32_t flags = SET_PRELOCK_FLAG(0);
THD* thd = ha_thd();
tokudb_trx_data* trx = (tokudb_trx_data *) thd_data_get(thd, tokudb_hton->slot);;
HANDLE_INVALID_CURSOR();
......@@ -5287,7 +5287,7 @@ int ha_tokudb::index_last(uchar * buf) {
invalidate_bulk_fetch();
int error = 0;
struct smart_dbt_info info;
u_int32_t flags = SET_PRELOCK_FLAG(0);
uint32_t flags = SET_PRELOCK_FLAG(0);
THD* thd = ha_thd();
tokudb_trx_data* trx = (tokudb_trx_data *) thd_data_get(thd, tokudb_hton->slot);;
HANDLE_INVALID_CURSOR();
......@@ -5430,8 +5430,8 @@ DBT *ha_tokudb::get_pos(DBT * to, uchar * pos) {
TOKUDB_DBUG_ENTER("ha_tokudb::get_pos");
/* We don't need to set app_data here */
memset((void *) to, 0, sizeof(*to));
to->data = pos + sizeof(u_int32_t);
to->size = *(u_int32_t *)pos;
to->data = pos + sizeof(uint32_t);
to->size = *(uint32_t *)pos;
DBUG_DUMP("key", (const uchar *) to->data, to->size);
DBUG_RETURN(to);
}
......@@ -5613,20 +5613,20 @@ void ha_tokudb::position(const uchar * record) {
TOKUDB_DBUG_ENTER("ha_tokudb::position");
DBT key;
if (hidden_primary_key) {
DBUG_ASSERT(ref_length == (TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH + sizeof(u_int32_t)));
memcpy_fixed(ref + sizeof(u_int32_t), current_ident, TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH);
*(u_int32_t *)ref = TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH;
DBUG_ASSERT(ref_length == (TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH + sizeof(uint32_t)));
memcpy_fixed(ref + sizeof(uint32_t), current_ident, TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH);
*(uint32_t *)ref = TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH;
}
else {
bool has_null;
//
// save the data
//
create_dbt_key_from_table(&key, primary_key, ref + sizeof(u_int32_t), record, &has_null);
create_dbt_key_from_table(&key, primary_key, ref + sizeof(uint32_t), record, &has_null);
//
// save the size of data in the first four bytes of ref
//
memcpy(ref, &key.size, sizeof(u_int32_t));
memcpy(ref, &key.size, sizeof(uint32_t));
}
DBUG_VOID_RETURN;
}
......@@ -5652,7 +5652,7 @@ int ha_tokudb::info(uint flag) {
}
stats.deleted = 0;
if (!(flag & HA_STATUS_NO_LOCK)) {
u_int64_t num_rows = 0;
uint64_t num_rows = 0;
TOKU_DB_FRAGMENTATION_S frag_info;
memset(&frag_info, 0, sizeof frag_info);
......@@ -5698,14 +5698,14 @@ int ha_tokudb::info(uint flag) {
// in this case, we have a hidden primary key, do not
// want to report space taken up by the hidden primary key to the user
//
u_int64_t hpk_space = TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH*dict_stats.bt_ndata;
uint64_t hpk_space = TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH*dict_stats.bt_ndata;
stats.data_file_length = (hpk_space > stats.data_file_length) ? 0 : stats.data_file_length - hpk_space;
}
else {
//
// one infinity byte per key needs to be subtracted
//
u_int64_t inf_byte_space = dict_stats.bt_ndata;
uint64_t inf_byte_space = dict_stats.bt_ndata;
stats.data_file_length = (inf_byte_space > stats.data_file_length) ? 0 : stats.data_file_length - inf_byte_space;
}
......@@ -5875,7 +5875,7 @@ int ha_tokudb::create_txn(THD* thd, tokudb_trx_data* trx) {
TOKUDB_TRACE("just created master:%p\n", trx->all);
}
trx->sp_level = trx->all;
trans_register_ha(thd, TRUE, tokudb_hton);
trans_register_ha(thd, true, tokudb_hton);
}
DBUG_PRINT("trans", ("starting transaction stmt"));
if (trx->stmt) {
......@@ -5883,7 +5883,7 @@ int ha_tokudb::create_txn(THD* thd, tokudb_trx_data* trx) {
TOKUDB_TRACE("warning:stmt=%p\n", trx->stmt);
}
}
u_int32_t txn_begin_flags;
uint32_t txn_begin_flags;
if (trx->all == NULL) {
txn_begin_flags = toku_iso_to_txn_flag(toku_iso_level);
if (txn_begin_flags == 0 && is_autocommit && thd_sql_command(thd) == SQLCOM_SELECT) {
......@@ -5903,7 +5903,7 @@ int ha_tokudb::create_txn(THD* thd, tokudb_trx_data* trx) {
TOKUDB_TRACE("just created stmt:%p:%p\n", trx->sp_level, trx->stmt);
}
reset_stmt_progress(&trx->stmt_progress);
trans_register_ha(thd, FALSE, tokudb_hton);
trans_register_ha(thd, false, tokudb_hton);
cleanup:
return error;
}
......@@ -6062,13 +6062,13 @@ int ha_tokudb::start_stmt(THD * thd, thr_lock_type lock_type) {
share->rows_from_locked_table = added_rows - deleted_rows;
}
transaction = trx->sub_sp_level;
trans_register_ha(thd, FALSE, tokudb_hton);
trans_register_ha(thd, false, tokudb_hton);
cleanup:
TOKUDB_DBUG_RETURN(error);
}
u_int32_t ha_tokudb::get_cursor_isolation_flags(enum thr_lock_type lock_type, THD* thd) {
uint32_t ha_tokudb::get_cursor_isolation_flags(enum thr_lock_type lock_type, THD* thd) {
uint sql_command = thd_sql_command(thd);
bool in_lock_tables = thd_in_lock_tables(thd);
......@@ -6241,7 +6241,7 @@ static int create_sub_table(
TOKUDB_DBUG_ENTER("create_sub_table");
int error;
DB *file = NULL;
u_int32_t create_flags;
uint32_t create_flags;
error = db_create(&file, db_env, 0);
......@@ -6392,22 +6392,22 @@ void ha_tokudb::trace_create_table_info(const char *name, TABLE * form) {
}
}
static u_int32_t get_max_desc_size(KEY_AND_COL_INFO* kc_info, TABLE* form) {
u_int32_t max_row_desc_buff_size;
static uint32_t get_max_desc_size(KEY_AND_COL_INFO* kc_info, TABLE* form) {
uint32_t max_row_desc_buff_size;
max_row_desc_buff_size = 2*(form->s->fields * 6)+10; // upper bound of key comparison descriptor
max_row_desc_buff_size += get_max_secondary_key_pack_desc_size(kc_info); // upper bound for sec. key part
max_row_desc_buff_size += get_max_clustering_val_pack_desc_size(form->s); // upper bound for clustering val part
return max_row_desc_buff_size;
}
static u_int32_t create_secondary_key_descriptor(
static uint32_t create_secondary_key_descriptor(
uchar* buf,
KEY* key_info,
KEY* prim_key,
uint hpk,
TABLE* form,
uint primary_key,
u_int32_t keynr,
uint32_t keynr,
KEY_AND_COL_INFO* kc_info
)
{
......@@ -6453,7 +6453,7 @@ int ha_tokudb::create_secondary_dictionary(
KEY* key_info,
DB_TXN* txn,
KEY_AND_COL_INFO* kc_info,
u_int32_t keynr,
uint32_t keynr,
bool is_hot_index,
enum row_type row_type
)
......@@ -6464,7 +6464,7 @@ int ha_tokudb::create_secondary_dictionary(
char* newname = NULL;
KEY* prim_key = NULL;
char dict_name[MAX_DICT_NAME_LEN];
u_int32_t max_row_desc_buff_size;
uint32_t max_row_desc_buff_size;
uint hpk= (form->s->primary_key >= MAX_KEY) ? TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH : 0;
uint32_t block_size;
uint32_t read_block_size;
......@@ -6518,7 +6518,7 @@ int ha_tokudb::create_secondary_dictionary(
}
static u_int32_t create_main_key_descriptor(
static uint32_t create_main_key_descriptor(
uchar* buf,
KEY* prim_key,
uint hpk,
......@@ -6561,7 +6561,7 @@ int ha_tokudb::create_main_dictionary(const char* name, TABLE* form, DB_TXN* txn
uchar* row_desc_buff = NULL;
char* newname = NULL;
KEY* prim_key = NULL;
u_int32_t max_row_desc_buff_size;
uint32_t max_row_desc_buff_size;
uint hpk= (form->s->primary_key >= MAX_KEY) ? TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH : 0;
uint32_t block_size;
uint32_t read_block_size;
......@@ -7115,9 +7115,9 @@ ha_rows ha_tokudb::records_in_range(uint keynr, key_range* start_key, key_range*
DBT key;
ha_rows ret_val = HA_TOKUDB_RANGE_COUNT;
DB *kfile = share->key_file[keynr];
u_int64_t less, equal, greater;
u_int64_t total_rows_estimate = HA_TOKUDB_RANGE_COUNT;
u_int64_t start_rows, end_rows, rows;
uint64_t less, equal, greater;
uint64_t total_rows_estimate = HA_TOKUDB_RANGE_COUNT;
uint64_t start_rows, end_rows, rows;
int is_exact;
int error;
uchar inf_byte;
......@@ -7364,11 +7364,11 @@ int ha_tokudb::tokudb_add_index(
DB_INDEXER* indexer = NULL;
bool loader_use_puts = get_load_save_space(thd);
bool use_hot_index = (lock.type == TL_WRITE_ALLOW_WRITE);
u_int32_t loader_flags = loader_use_puts ? LOADER_USE_PUTS : 0;
u_int32_t indexer_flags = 0;
u_int32_t mult_db_flags[MAX_KEY + 1] = {0};
u_int32_t mult_put_flags[MAX_KEY + 1];
u_int32_t mult_dbt_flags[MAX_KEY + 1];
uint32_t loader_flags = loader_use_puts ? LOADER_USE_PUTS : 0;
uint32_t indexer_flags = 0;
uint32_t mult_db_flags[MAX_KEY + 1] = {0};
uint32_t mult_put_flags[MAX_KEY + 1];
uint32_t mult_dbt_flags[MAX_KEY + 1];
bool creating_hot_index = false;
struct loader_context lc;
memset(&lc, 0, sizeof lc);
......@@ -7380,7 +7380,7 @@ int ha_tokudb::tokudb_add_index(
*modified_DBs = false;
invalidate_bulk_fetch();
unpack_entire_row = true; // for bulk fetching rows
for (u_int32_t i = 0; i < MAX_KEY+1; i++) {
for (uint32_t i = 0; i < MAX_KEY+1; i++) {
mult_put_flags[i] = 0;
mult_dbt_flags[i] = DB_DBT_REALLOC;
}
......@@ -7526,7 +7526,7 @@ int ha_tokudb::tokudb_add_index(
// you need the val if you have a clustering index and key_read is not 0;
bf_info.direction = 1;
bf_info.thd = ha_thd();
bf_info.need_val = TRUE;
bf_info.need_val = true;
error = db_env->create_loader(
db_env,
......@@ -7596,14 +7596,14 @@ int ha_tokudb::tokudb_add_index(
// at this point, we know the range query buffer has at least one key/val pair
uchar* curr_pos = range_query_buff+curr_range_query_buff_offset;
u_int32_t key_size = *(u_int32_t *)curr_pos;
uint32_t key_size = *(uint32_t *)curr_pos;
curr_pos += sizeof(key_size);
uchar* curr_key_buff = curr_pos;
curr_pos += key_size;
curr_pk_key.data = curr_key_buff;
curr_pk_key.size = key_size;
u_int32_t val_size = *(u_int32_t *)curr_pos;
uint32_t val_size = *(uint32_t *)curr_pos;
curr_pos += sizeof(val_size);
uchar* curr_val_buff = curr_pos;
curr_pos += val_size;
......
......@@ -81,7 +81,7 @@ typedef struct st_tokudb_share {
bool has_unique_keys;
bool replace_into_fast;
rw_lock_t num_DBs_lock;
u_int32_t num_DBs;
uint32_t num_DBs;
} TOKUDB_SHARE;
#define HA_TOKU_ORIG_VERSION 4
......@@ -149,12 +149,12 @@ class ha_tokudb : public handler {
//
uchar *rec_update_buff;
ulong alloced_update_rec_buff_length;
u_int32_t max_key_length;
uint32_t max_key_length;
uchar* range_query_buff; // range query buffer
u_int32_t size_range_query_buff; // size of the allocated range query buffer
u_int32_t bytes_used_in_range_query_buff; // number of bytes used in the range query buffer
u_int32_t curr_range_query_buff_offset; // current offset into the range query buffer for queries to read
uint32_t size_range_query_buff; // size of the allocated range query buffer
uint32_t bytes_used_in_range_query_buff; // number of bytes used in the range query buffer
uint32_t curr_range_query_buff_offset; // current offset into the range query buffer for queries to read
uint64_t bulk_fetch_iteration;
uint64_t rows_fetched_using_bulk_fetch;
bool doing_bulk_fetch;
......@@ -185,9 +185,9 @@ class ha_tokudb : public handler {
// ranges of prelocked area, used to know how much to bulk fetch
//
uchar *prelocked_left_range;
u_int32_t prelocked_left_range_size;
uint32_t prelocked_left_range_size;
uchar *prelocked_right_range;
u_int32_t prelocked_right_range_size;
uint32_t prelocked_right_range_size;
//
......@@ -195,9 +195,9 @@ class ha_tokudb : public handler {
//
DBT mult_key_dbt[2*(MAX_KEY + 1)];
DBT mult_rec_dbt[MAX_KEY + 1];
u_int32_t mult_put_flags[MAX_KEY + 1];
u_int32_t mult_del_flags[MAX_KEY + 1];
u_int32_t mult_dbt_flags[MAX_KEY + 1];
uint32_t mult_put_flags[MAX_KEY + 1];
uint32_t mult_del_flags[MAX_KEY + 1];
uint32_t mult_dbt_flags[MAX_KEY + 1];
//
......@@ -207,7 +207,7 @@ class ha_tokudb : public handler {
// query
//
uchar* blob_buff;
u_int32_t num_blob_bytes;
uint32_t num_blob_bytes;
bool unpack_entire_row;
......@@ -215,10 +215,10 @@ class ha_tokudb : public handler {
// buffers (and their sizes) that will hold the indexes
// of fields that need to be read for a query
//
u_int32_t* fixed_cols_for_query;
u_int32_t num_fixed_cols_for_query;
u_int32_t* var_cols_for_query;
u_int32_t num_var_cols_for_query;
uint32_t* fixed_cols_for_query;
uint32_t num_fixed_cols_for_query;
uint32_t* var_cols_for_query;
uint32_t num_var_cols_for_query;
bool read_blobs;
bool read_key;
......@@ -235,7 +235,7 @@ class ha_tokudb : public handler {
// instance of cursor being used for init_xxx and rnd_xxx functions
//
DBC *cursor;
u_int32_t cursor_flags; // flags for cursor
uint32_t cursor_flags; // flags for cursor
//
// flags that are returned in table_flags()
//
......@@ -265,7 +265,7 @@ class ha_tokudb : public handler {
//
// For instances where we successfully prelock a range or a table,
// we set this to TRUE so that successive cursor calls can know
// we set this to true so that successive cursor calls can know
// know to limit the locking overhead in a call to the fractal tree
//
bool range_lock_grabbed;
......@@ -291,7 +291,7 @@ class ha_tokudb : public handler {
int loader_error;
bool num_DBs_locked_in_bulk;
u_int32_t lock_count;
uint32_t lock_count;
bool fix_rec_buff_for_blob(ulong length);
bool fix_rec_update_buff_for_blob(ulong length);
......@@ -314,9 +314,9 @@ class ha_tokudb : public handler {
const uchar* record,
uint index
);
u_int32_t place_key_into_mysql_buff(KEY* key_info, uchar * record, uchar* data);
uint32_t place_key_into_mysql_buff(KEY* key_info, uchar * record, uchar* data);
void unpack_key(uchar * record, DBT const *key, uint index);
u_int32_t place_key_into_dbt_buff(KEY* key_info, uchar * buff, const uchar * record, bool* has_null, int key_length);
uint32_t place_key_into_dbt_buff(KEY* key_info, uchar * buff, const uchar * record, bool* has_null, int key_length);
DBT* create_dbt_key_from_key(DBT * key, KEY* key_info, uchar * buff, const uchar * record, bool* has_null, bool dont_pack_pk, int key_length = MAX_KEY_LENGTH);
DBT *create_dbt_key_from_table(DBT * key, uint keynr, uchar * buff, const uchar * record, bool* has_null, int key_length = MAX_KEY_LENGTH);
DBT* create_dbt_key_for_lookup(DBT * key, KEY* key_info, uchar * buff, const uchar * record, bool* has_null, int key_length = MAX_KEY_LENGTH);
......@@ -328,7 +328,7 @@ class ha_tokudb : public handler {
int open_main_dictionary(const char* name, bool is_read_only, DB_TXN* txn);
int open_secondary_dictionary(DB** ptr, KEY* key_info, const char* name, bool is_read_only, DB_TXN* txn);
int acquire_table_lock (DB_TXN* trans, TABLE_LOCK_TYPE lt);
int estimate_num_rows(DB* db, u_int64_t* num_rows, DB_TXN* txn);
int estimate_num_rows(DB* db, uint64_t* num_rows, DB_TXN* txn);
bool has_auto_increment_flag(uint* index);
int write_frm_data(DB* db, DB_TXN* txn, const char* frm_name);
......@@ -365,7 +365,7 @@ class ha_tokudb : public handler {
KEY* key_info,
DB_TXN* txn,
KEY_AND_COL_INFO* kc_info,
u_int32_t keynr,
uint32_t keynr,
bool is_hot_index,
enum row_type row_type
);
......@@ -374,17 +374,17 @@ class ha_tokudb : public handler {
int is_index_unique(bool* is_unique, DB_TXN* txn, DB* db, KEY* key_info);
int is_val_unique(bool* is_unique, uchar* record, KEY* key_info, uint dict_index, DB_TXN* txn);
int do_uniqueness_checks(uchar* record, DB_TXN* txn, THD* thd);
void set_main_dict_put_flags(THD* thd, bool opt_eligible, u_int32_t* put_flags);
void set_main_dict_put_flags(THD* thd, bool opt_eligible, uint32_t* put_flags);
int insert_row_to_main_dictionary(uchar* record, DBT* pk_key, DBT* pk_val, DB_TXN* txn);
int insert_rows_to_dictionaries_mult(DBT* pk_key, DBT* pk_val, DB_TXN* txn, THD* thd);
void test_row_packing(uchar* record, DBT* pk_key, DBT* pk_val);
u_int32_t fill_row_mutator(
uint32_t fill_row_mutator(
uchar* buf,
u_int32_t* dropped_columns,
u_int32_t num_dropped_columns,
uint32_t* dropped_columns,
uint32_t num_dropped_columns,
TABLE* altered_table,
KEY_AND_COL_INFO* altered_kc_info,
u_int32_t keynr,
uint32_t keynr,
bool is_add
);
......@@ -490,7 +490,7 @@ class ha_tokudb : public handler {
ha_rows records_in_range(uint inx, key_range * min_key, key_range * max_key);
u_int32_t get_cursor_isolation_flags(enum thr_lock_type lock_type, THD* thd);
uint32_t get_cursor_isolation_flags(enum thr_lock_type lock_type, THD* thd);
THR_LOCK_DATA **store_lock(THD * thd, THR_LOCK_DATA ** to, enum thr_lock_type lock_type);
int get_status(DB_TXN* trans);
......@@ -609,7 +609,7 @@ class ha_tokudb : public handler {
int unpack_blobs(
uchar* record,
const uchar* from_tokudb_blob,
u_int32_t num_blob_bytes,
uint32_t num_blob_bytes,
bool check_bitmap
);
int unpack_row(
......
......@@ -306,8 +306,8 @@ ha_tokudb::check_if_supported_alter(TABLE *altered_table,
goto cleanup;
}
if (has_added_columns && !has_non_added_changes) {
u_int32_t added_columns[altered_table->s->fields];
u_int32_t num_added_columns = 0;
uint32_t added_columns[altered_table->s->fields];
uint32_t num_added_columns = 0;
int r = find_changed_columns(
added_columns,
&num_added_columns,
......@@ -319,8 +319,8 @@ ha_tokudb::check_if_supported_alter(TABLE *altered_table,
goto cleanup;
}
if (tokudb_debug & TOKUDB_DEBUG_ALTER_TABLE_INFO) {
for (u_int32_t i = 0; i < num_added_columns; i++) {
u_int32_t curr_added_index = added_columns[i];
for (uint32_t i = 0; i < num_added_columns; i++) {
uint32_t curr_added_index = added_columns[i];
Field* curr_added_field = altered_table->field[curr_added_index];
printf(
"Added column: index %d, name %s\n",
......@@ -331,8 +331,8 @@ ha_tokudb::check_if_supported_alter(TABLE *altered_table,
}
}
if (has_dropped_columns && !has_non_dropped_changes) {
u_int32_t dropped_columns[table->s->fields];
u_int32_t num_dropped_columns = 0;
uint32_t dropped_columns[table->s->fields];
uint32_t num_dropped_columns = 0;
int r = find_changed_columns(
dropped_columns,
&num_dropped_columns,
......@@ -344,8 +344,8 @@ ha_tokudb::check_if_supported_alter(TABLE *altered_table,
goto cleanup;
}
if (tokudb_debug & TOKUDB_DEBUG_ALTER_TABLE_INFO) {
for (u_int32_t i = 0; i < num_dropped_columns; i++) {
u_int32_t curr_dropped_index = dropped_columns[i];
for (uint32_t i = 0; i < num_dropped_columns; i++) {
uint32_t curr_dropped_index = dropped_columns[i];
Field* curr_dropped_field = table->field[curr_dropped_index];
printf(
"Dropped column: index %d, name %s\n",
......@@ -420,7 +420,7 @@ ha_tokudb::alter_table_phase2(
bool has_row_format_changes = alter_flags->is_set(HA_ALTER_ROW_FORMAT);
KEY_AND_COL_INFO altered_kc_info;
memset(&altered_kc_info, 0, sizeof(altered_kc_info));
u_int32_t max_new_desc_size = 0;
uint32_t max_new_desc_size = 0;
uchar* row_desc_buff = NULL;
uchar* column_extra = NULL;
bool dropping_indexes = alter_info->index_drop_count > 0 && !tables_have_same_keys(table,altered_table,false, false);
......@@ -504,11 +504,11 @@ ha_tokudb::alter_table_phase2(
if (has_dropped_columns || has_added_columns) {
DBT column_dbt;
memset(&column_dbt, 0, sizeof(DBT));
u_int32_t max_column_extra_size;
u_int32_t num_column_extra;
u_int32_t columns[table->s->fields + altered_table->s->fields]; // set size such that we know it is big enough for both cases
u_int32_t num_columns = 0;
u_int32_t curr_num_DBs = table->s->keys + test(hidden_primary_key);
uint32_t max_column_extra_size;
uint32_t num_column_extra;
uint32_t columns[table->s->fields + altered_table->s->fields]; // set size such that we know it is big enough for both cases
uint32_t num_columns = 0;
uint32_t curr_num_DBs = table->s->keys + test(hidden_primary_key);
memset(columns, 0, sizeof(columns));
if (has_added_columns && has_dropped_columns) {
......@@ -554,7 +554,7 @@ ha_tokudb::alter_table_phase2(
column_extra = (uchar *)my_malloc(max_column_extra_size, MYF(MY_WME));
if (column_extra == NULL) { error = ENOMEM; goto cleanup; }
for (u_int32_t i = 0; i < curr_num_DBs; i++) {
for (uint32_t i = 0; i < curr_num_DBs; i++) {
DBT row_descriptor;
memset(&row_descriptor, 0, sizeof(row_descriptor));
KEY* prim_key = (hidden_primary_key) ? NULL : &altered_table->s->key_info[primary_key];
......@@ -624,8 +624,8 @@ ha_tokudb::alter_table_phase2(
method = row_type_to_compression_method(create_info->row_type);
// Set the new type.
u_int32_t curr_num_DBs = table->s->keys + test(hidden_primary_key);
for (u_int32_t i = 0; i < curr_num_DBs; ++i) {
uint32_t curr_num_DBs = table->s->keys + test(hidden_primary_key);
for (uint32_t i = 0; i < curr_num_DBs; ++i) {
DB *db = share->key_file[i];
error = db->change_compression_method(db, method);
if (error) {
......
......@@ -158,13 +158,13 @@ ha_tokudb::check_if_supported_inplace_alter(TABLE *altered_table, Alter_inplace_
} else
// add column
if (only_flags(handler_flags, Alter_inplace_info::ADD_COLUMN + Alter_inplace_info::ALTER_COLUMN_ORDER)) {
u_int32_t added_columns[altered_table->s->fields];
u_int32_t num_added_columns = 0;
uint32_t added_columns[altered_table->s->fields];
uint32_t num_added_columns = 0;
int r = find_changed_columns(added_columns, &num_added_columns, table, altered_table);
if (r == 0) {
if (tokudb_debug & TOKUDB_DEBUG_ALTER_TABLE_INFO) {
for (u_int32_t i = 0; i < num_added_columns; i++) {
u_int32_t curr_added_index = added_columns[i];
for (uint32_t i = 0; i < num_added_columns; i++) {
uint32_t curr_added_index = added_columns[i];
Field* curr_added_field = altered_table->field[curr_added_index];
printf("Added column: index %d, name %s\n", curr_added_index, curr_added_field->field_name);
}
......@@ -174,13 +174,13 @@ ha_tokudb::check_if_supported_inplace_alter(TABLE *altered_table, Alter_inplace_
} else
// drop column
if (only_flags(handler_flags, Alter_inplace_info::DROP_COLUMN + Alter_inplace_info::ALTER_COLUMN_ORDER)) {
u_int32_t dropped_columns[table->s->fields];
u_int32_t num_dropped_columns = 0;
uint32_t dropped_columns[table->s->fields];
uint32_t num_dropped_columns = 0;
int r = find_changed_columns(dropped_columns, &num_dropped_columns, altered_table, table);
if (r == 0) {
if (tokudb_debug & TOKUDB_DEBUG_ALTER_TABLE_INFO) {
for (u_int32_t i = 0; i < num_dropped_columns; i++) {
u_int32_t curr_dropped_index = dropped_columns[i];
for (uint32_t i = 0; i < num_dropped_columns; i++) {
uint32_t curr_dropped_index = dropped_columns[i];
Field* curr_dropped_field = table->field[curr_dropped_index];
printf("Dropped column: index %d, name %s\n", curr_dropped_index, curr_dropped_field->field_name);
}
......@@ -248,8 +248,8 @@ ha_tokudb::inplace_alter_table(TABLE *altered_table, Alter_inplace_info *ha_alte
assert(error == 0);
ctx->compression_changed = true;
// Set the new type.
u_int32_t curr_num_DBs = table->s->keys + test(hidden_primary_key);
for (u_int32_t i = 0; i < curr_num_DBs; i++) {
uint32_t curr_num_DBs = table->s->keys + test(hidden_primary_key);
for (uint32_t i = 0; i < curr_num_DBs; i++) {
db = share->key_file[i];
error = db->change_compression_method(db, method);
if (error)
......@@ -315,13 +315,13 @@ ha_tokudb::alter_table_add_or_drop_column(TABLE *altered_table, Alter_inplace_in
int error;
uchar *column_extra = NULL;
uchar *row_desc_buff = NULL;
u_int32_t max_new_desc_size = 0;
u_int32_t max_column_extra_size;
u_int32_t num_column_extra;
u_int32_t num_columns = 0;
u_int32_t curr_num_DBs = table->s->keys + test(hidden_primary_key);
uint32_t max_new_desc_size = 0;
uint32_t max_column_extra_size;
uint32_t num_column_extra;
uint32_t num_columns = 0;
uint32_t curr_num_DBs = table->s->keys + test(hidden_primary_key);
u_int32_t columns[table->s->fields + altered_table->s->fields]; // set size such that we know it is big enough for both cases
uint32_t columns[table->s->fields + altered_table->s->fields]; // set size such that we know it is big enough for both cases
memset(columns, 0, sizeof(columns));
KEY_AND_COL_INFO altered_kc_info;
......@@ -369,7 +369,7 @@ ha_tokudb::alter_table_add_or_drop_column(TABLE *altered_table, Alter_inplace_in
column_extra = (uchar *)my_malloc(max_column_extra_size, MYF(MY_WME));
if (column_extra == NULL) { error = ENOMEM; goto cleanup; }
for (u_int32_t i = 0; i < curr_num_DBs; i++) {
for (uint32_t i = 0; i < curr_num_DBs; i++) {
DBT row_descriptor;
memset(&row_descriptor, 0, sizeof(row_descriptor));
KEY* prim_key = (hidden_primary_key) ? NULL : &altered_table->s->key_info[primary_key];
......@@ -495,8 +495,8 @@ ha_tokudb::commit_inplace_alter_table(TABLE *altered_table, Alter_inplace_info *
restore_drop_indexes(table, index_drop_offsets, ha_alter_info->index_drop_count);
}
if (ctx->compression_changed) {
u_int32_t curr_num_DBs = table->s->keys + test(hidden_primary_key);
for (u_int32_t i = 0; i < curr_num_DBs; i++) {
uint32_t curr_num_DBs = table->s->keys + test(hidden_primary_key);
for (uint32_t i = 0; i < curr_num_DBs; i++) {
DB *db = share->key_file[i];
int error = db->change_compression_method(db, ctx->orig_compression_method);
assert(error == 0);
......
......@@ -19,7 +19,7 @@ tables_have_same_keys(TABLE* table, TABLE* altered_table, bool print_error, bool
retval = false;
goto cleanup;
}
for (u_int32_t i=0; i < table->s->keys; i++) {
for (uint32_t i=0; i < table->s->keys; i++) {
KEY* curr_orig_key = &table->key_info[i];
KEY* curr_altered_key = &altered_table->key_info[i];
if (strcmp(curr_orig_key->name, curr_altered_key->name)) {
......@@ -70,7 +70,7 @@ tables_have_same_keys(TABLE* table, TABLE* altered_table, bool print_error, bool
//
// now verify that each field in the key is the same
//
for (u_int32_t j = 0; j < curr_orig_key->key_parts; j++) {
for (uint32_t j = 0; j < curr_orig_key->key_parts; j++) {
KEY_PART_INFO* curr_orig_part = &curr_orig_key->key_part[j];
KEY_PART_INFO* curr_altered_part = &curr_altered_key->key_part[j];
Field* curr_orig_field = curr_orig_part->field;
......@@ -115,9 +115,9 @@ tables_have_same_keys(TABLE* table, TABLE* altered_table, bool print_error, bool
// to evaluate whether a field is NULL or not. This value is a power of 2, from
// 2^0 to 2^7. We return the position of the bit within the byte, which is
// lg null_bit
static inline u_int32_t
get_null_bit_position(u_int32_t null_bit) {
u_int32_t retval = 0;
static inline uint32_t
get_null_bit_position(uint32_t null_bit) {
uint32_t retval = 0;
switch(null_bit) {
case (1):
retval = 0;
......@@ -150,24 +150,24 @@ get_null_bit_position(u_int32_t null_bit) {
}
// returns the index of the null bit of field.
static inline u_int32_t
static inline uint32_t
get_overall_null_bit_position(TABLE* table, Field* field) {
u_int32_t offset = get_null_offset(table, field);
u_int32_t null_bit = field->null_bit;
uint32_t offset = get_null_offset(table, field);
uint32_t null_bit = field->null_bit;
return offset*8 + get_null_bit_position(null_bit);
}
// not static since 51 uses this and 56 does not
bool
are_null_bits_in_order(TABLE* table) {
u_int32_t curr_null_pos = 0;
uint32_t curr_null_pos = 0;
bool first = true;
bool retval = true;
for (uint i = 0; i < table->s->fields; i++) {
Field* curr_field = table->field[i];
bool nullable = (curr_field->null_bit != 0);
if (nullable) {
u_int32_t pos = get_overall_null_bit_position(
uint32_t pos = get_overall_null_bit_position(
table,
curr_field
);
......@@ -182,9 +182,9 @@ are_null_bits_in_order(TABLE* table) {
return retval;
}
static u_int32_t
static uint32_t
get_first_null_bit_pos(TABLE* table) {
u_int32_t table_pos = 0;
uint32_t table_pos = 0;
for (uint i = 0; i < table->s->fields; i++) {
Field* curr_field = table->field[i];
bool nullable = (curr_field->null_bit != 0);
......@@ -201,12 +201,12 @@ get_first_null_bit_pos(TABLE* table) {
#if 0
static bool
is_column_default_null(TABLE* src_table, u_int32_t field_index) {
is_column_default_null(TABLE* src_table, uint32_t field_index) {
Field* curr_field = src_table->field[field_index];
bool is_null_default = false;
bool nullable = curr_field->null_bit != 0;
if (nullable) {
u_int32_t null_bit_position = get_overall_null_bit_position(src_table, curr_field);
uint32_t null_bit_position = get_overall_null_bit_position(src_table, curr_field);
is_null_default = is_overall_null_position_set(
src_table->s->default_values,
null_bit_position
......@@ -216,14 +216,14 @@ is_column_default_null(TABLE* src_table, u_int32_t field_index) {
}
#endif
static u_int32_t
static uint32_t
fill_static_row_mutator(
uchar* buf,
TABLE* orig_table,
TABLE* altered_table,
KEY_AND_COL_INFO* orig_kc_info,
KEY_AND_COL_INFO* altered_kc_info,
u_int32_t keynr
uint32_t keynr
)
{
//
......@@ -255,7 +255,7 @@ fill_static_row_mutator(
//
// size of fixed fields
//
u_int32_t fixed_field_size = orig_kc_info->mcp_info[keynr].fixed_field_size;
uint32_t fixed_field_size = orig_kc_info->mcp_info[keynr].fixed_field_size;
memcpy(pos, &fixed_field_size, sizeof(fixed_field_size));
pos += sizeof(fixed_field_size);
fixed_field_size = altered_kc_info->mcp_info[keynr].fixed_field_size;
......@@ -265,17 +265,17 @@ fill_static_row_mutator(
//
// length of offsets
//
u_int32_t len_of_offsets = orig_kc_info->mcp_info[keynr].len_of_offsets;
uint32_t len_of_offsets = orig_kc_info->mcp_info[keynr].len_of_offsets;
memcpy(pos, &len_of_offsets, sizeof(len_of_offsets));
pos += sizeof(len_of_offsets);
len_of_offsets = altered_kc_info->mcp_info[keynr].len_of_offsets;
memcpy(pos, &len_of_offsets, sizeof(len_of_offsets));
pos += sizeof(len_of_offsets);
u_int32_t orig_start_null_pos = get_first_null_bit_pos(orig_table);
uint32_t orig_start_null_pos = get_first_null_bit_pos(orig_table);
memcpy(pos, &orig_start_null_pos, sizeof(orig_start_null_pos));
pos += sizeof(orig_start_null_pos);
u_int32_t altered_start_null_pos = get_first_null_bit_pos(altered_table);
uint32_t altered_start_null_pos = get_first_null_bit_pos(altered_table);
memcpy(pos, &altered_start_null_pos, sizeof(altered_start_null_pos));
pos += sizeof(altered_start_null_pos);
......@@ -283,25 +283,25 @@ fill_static_row_mutator(
return pos - buf;
}
static u_int32_t
static uint32_t
fill_dynamic_row_mutator(
uchar* buf,
u_int32_t* columns,
u_int32_t num_columns,
uint32_t* columns,
uint32_t num_columns,
TABLE* src_table,
KEY_AND_COL_INFO* src_kc_info,
u_int32_t keynr,
uint32_t keynr,
bool is_add,
bool* out_has_blobs
)
{
uchar* pos = buf;
bool has_blobs = false;
u_int32_t cols = num_columns;
uint32_t cols = num_columns;
memcpy(pos, &cols, sizeof(cols));
pos += sizeof(cols);
for (u_int32_t i = 0; i < num_columns; i++) {
u_int32_t curr_index = columns[i];
for (uint32_t i = 0; i < num_columns; i++) {
uint32_t curr_index = columns[i];
Field* curr_field = src_table->field[curr_index];
pos[0] = is_add ? COL_ADD : COL_DROP;
......@@ -319,7 +319,7 @@ fill_dynamic_row_mutator(
pos[0] = 1;
pos++;
// write position of null byte that is to be removed
u_int32_t null_bit_position = get_overall_null_bit_position(src_table, curr_field);
uint32_t null_bit_position = get_overall_null_bit_position(src_table, curr_field);
memcpy(pos, &null_bit_position, sizeof(null_bit_position));
pos += sizeof(null_bit_position);
//
......@@ -340,11 +340,11 @@ fill_dynamic_row_mutator(
pos[0] = COL_FIXED;
pos++;
//store the offset
u_int32_t fixed_field_offset = src_kc_info->cp_info[keynr][curr_index].col_pack_val;
uint32_t fixed_field_offset = src_kc_info->cp_info[keynr][curr_index].col_pack_val;
memcpy(pos, &fixed_field_offset, sizeof(fixed_field_offset));
pos += sizeof(fixed_field_offset);
//store the number of bytes
u_int32_t num_bytes = src_kc_info->field_lengths[curr_index];
uint32_t num_bytes = src_kc_info->field_lengths[curr_index];
memcpy(pos, &num_bytes, sizeof(num_bytes));
pos += sizeof(num_bytes);
if (is_add && !is_null_default) {
......@@ -361,13 +361,13 @@ fill_dynamic_row_mutator(
pos[0] = COL_VAR;
pos++;
//store the index of the variable column
u_int32_t var_field_index = src_kc_info->cp_info[keynr][curr_index].col_pack_val;
uint32_t var_field_index = src_kc_info->cp_info[keynr][curr_index].col_pack_val;
memcpy(pos, &var_field_index, sizeof(var_field_index));
pos += sizeof(var_field_index);
if (is_add && !is_null_default) {
uint curr_field_offset = field_offset(curr_field, src_table);
u_int32_t len_bytes = src_kc_info->length_bytes[curr_index];
u_int32_t data_length = get_var_data_length(
uint32_t len_bytes = src_kc_info->length_bytes[curr_index];
uint32_t data_length = get_var_data_length(
src_table->s->default_values + curr_field_offset,
len_bytes
);
......@@ -391,7 +391,7 @@ fill_dynamic_row_mutator(
return pos-buf;
}
static u_int32_t
static uint32_t
fill_static_blob_row_mutator(
uchar* buf,
TABLE* src_table,
......@@ -403,10 +403,10 @@ fill_static_blob_row_mutator(
memcpy(pos, &src_kc_info->num_blobs, sizeof(src_kc_info->num_blobs));
pos += sizeof(src_kc_info->num_blobs);
// copy length bytes for each blob
for (u_int32_t i = 0; i < src_kc_info->num_blobs; i++) {
u_int32_t curr_field_index = src_kc_info->blob_fields[i];
for (uint32_t i = 0; i < src_kc_info->num_blobs; i++) {
uint32_t curr_field_index = src_kc_info->blob_fields[i];
Field* field = src_table->field[curr_field_index];
u_int32_t len_bytes = field->row_pack_length();
uint32_t len_bytes = field->row_pack_length();
assert(len_bytes <= 4);
pos[0] = len_bytes;
pos++;
......@@ -415,27 +415,27 @@ fill_static_blob_row_mutator(
return pos-buf;
}
static u_int32_t
static uint32_t
fill_dynamic_blob_row_mutator(
uchar* buf,
u_int32_t* columns,
u_int32_t num_columns,
uint32_t* columns,
uint32_t num_columns,
TABLE* src_table,
KEY_AND_COL_INFO* src_kc_info,
bool is_add
)
{
uchar* pos = buf;
for (u_int32_t i = 0; i < num_columns; i++) {
u_int32_t curr_field_index = columns[i];
for (uint32_t i = 0; i < num_columns; i++) {
uint32_t curr_field_index = columns[i];
Field* curr_field = src_table->field[curr_field_index];
if (src_kc_info->field_lengths[curr_field_index] == 0 &&
src_kc_info->length_bytes[curr_field_index]== 0
)
{
// find out which blob it is
u_int32_t blob_index = src_kc_info->num_blobs;
for (u_int32_t j = 0; j < src_kc_info->num_blobs; j++) {
uint32_t blob_index = src_kc_info->num_blobs;
for (uint32_t j = 0; j < src_kc_info->num_blobs; j++) {
if (curr_field_index == src_kc_info->blob_fields[j]) {
blob_index = j;
break;
......@@ -448,7 +448,7 @@ fill_dynamic_blob_row_mutator(
memcpy(pos, &blob_index, sizeof(blob_index));
pos += sizeof(blob_index);
if (is_add) {
u_int32_t len_bytes = curr_field->row_pack_length();
uint32_t len_bytes = curr_field->row_pack_length();
assert(len_bytes <= 4);
pos[0] = len_bytes;
pos++;
......@@ -471,14 +471,14 @@ fill_dynamic_blob_row_mutator(
// TODO: carefully review to make sure that the right information is used
// TODO: namely, when do we get stuff from share->kc_info and when we get
// TODO: it from altered_kc_info, and when is keynr associated with the right thing
u_int32_t
uint32_t
ha_tokudb::fill_row_mutator(
uchar* buf,
u_int32_t* columns,
u_int32_t num_columns,
uint32_t* columns,
uint32_t num_columns,
TABLE* altered_table,
KEY_AND_COL_INFO* altered_kc_info,
u_int32_t keynr,
uint32_t keynr,
bool is_add
)
{
......@@ -626,15 +626,15 @@ column_rename_supported(
static int
find_changed_columns(
u_int32_t* changed_columns,
u_int32_t* num_changed_columns,
uint32_t* changed_columns,
uint32_t* num_changed_columns,
TABLE* smaller_table,
TABLE* bigger_table
)
{
int retval;
uint curr_new_col_index = 0;
u_int32_t curr_num_changed_columns=0;
uint32_t curr_num_changed_columns=0;
assert(bigger_table->s->fields > smaller_table->s->fields);
for (uint i = 0; i < smaller_table->s->fields; i++, curr_new_col_index++) {
if (curr_new_col_index >= bigger_table->s->fields) {
......
......@@ -54,8 +54,8 @@ So, upperbound is num_blobs(1+4+1+4) = num_columns*10
// checks whether the bit at index pos in data is set or not
//
static inline bool
is_overall_null_position_set(uchar* data, u_int32_t pos) {
u_int32_t offset = pos/8;
is_overall_null_position_set(uchar* data, uint32_t pos) {
uint32_t offset = pos/8;
uchar remainder = pos%8;
uchar null_bit = 1<<remainder;
return ((data[offset] & null_bit) != 0);
......@@ -65,8 +65,8 @@ is_overall_null_position_set(uchar* data, u_int32_t pos) {
// sets the bit at index pos in data to 1 if is_null, 0 otherwise
//
static inline void
set_overall_null_position(uchar* data, u_int32_t pos, bool is_null) {
u_int32_t offset = pos/8;
set_overall_null_position(uchar* data, uint32_t pos, bool is_null) {
uint32_t offset = pos/8;
uchar remainder = pos%8;
uchar null_bit = 1<<remainder;
if (is_null) {
......@@ -79,16 +79,16 @@ set_overall_null_position(uchar* data, u_int32_t pos, bool is_null) {
static inline void
copy_null_bits(
u_int32_t start_old_pos,
u_int32_t start_new_pos,
u_int32_t num_bits,
uint32_t start_old_pos,
uint32_t start_new_pos,
uint32_t num_bits,
uchar* old_null_bytes,
uchar* new_null_bytes
)
{
for (u_int32_t i = 0; i < num_bits; i++) {
u_int32_t curr_old_pos = i + start_old_pos;
u_int32_t curr_new_pos = i + start_new_pos;
for (uint32_t i = 0; i < num_bits; i++) {
uint32_t curr_old_pos = i + start_old_pos;
uint32_t curr_new_pos = i + start_new_pos;
// copy over old null bytes
if (is_overall_null_position_set(old_null_bytes,curr_old_pos)) {
set_overall_null_position(new_null_bytes,curr_new_pos,true);
......@@ -101,25 +101,25 @@ copy_null_bits(
static inline void
copy_var_fields(
u_int32_t start_old_num_var_field, //index of var fields that we should start writing
u_int32_t num_var_fields, // number of var fields to copy
uint32_t start_old_num_var_field, //index of var fields that we should start writing
uint32_t num_var_fields, // number of var fields to copy
uchar* old_var_field_offset_ptr, //static ptr to where offset bytes begin in old row
uchar old_num_offset_bytes, //number of offset bytes used in old row
uchar* start_new_var_field_data_ptr, // where the new var data should be written
uchar* start_new_var_field_offset_ptr, // where the new var offsets should be written
uchar* new_var_field_data_ptr, // pointer to beginning of var fields in new row
uchar* old_var_field_data_ptr, // pointer to beginning of var fields in old row
u_int32_t new_num_offset_bytes, // number of offset bytes used in new row
u_int32_t* num_data_bytes_written,
u_int32_t* num_offset_bytes_written
uint32_t new_num_offset_bytes, // number of offset bytes used in new row
uint32_t* num_data_bytes_written,
uint32_t* num_offset_bytes_written
)
{
uchar* curr_new_var_field_data_ptr = start_new_var_field_data_ptr;
uchar* curr_new_var_field_offset_ptr = start_new_var_field_offset_ptr;
for (u_int32_t i = 0; i < num_var_fields; i++) {
u_int32_t field_len;
u_int32_t start_read_offset;
u_int32_t curr_old = i + start_old_num_var_field;
for (uint32_t i = 0; i < num_var_fields; i++) {
uint32_t field_len;
uint32_t start_read_offset;
uint32_t curr_old = i + start_old_num_var_field;
uchar* data_to_copy = NULL;
// get the length and pointer to data that needs to be copied
get_var_field_info(
......@@ -141,13 +141,13 @@ copy_var_fields(
);
curr_new_var_field_offset_ptr += new_num_offset_bytes;
}
*num_data_bytes_written = (u_int32_t)(curr_new_var_field_data_ptr - start_new_var_field_data_ptr);
*num_offset_bytes_written = (u_int32_t)(curr_new_var_field_offset_ptr - start_new_var_field_offset_ptr);
*num_data_bytes_written = (uint32_t)(curr_new_var_field_data_ptr - start_new_var_field_data_ptr);
*num_offset_bytes_written = (uint32_t)(curr_new_var_field_offset_ptr - start_new_var_field_offset_ptr);
}
static inline u_int32_t
copy_toku_blob(uchar* to_ptr, uchar* from_ptr, u_int32_t len_bytes, bool skip) {
u_int32_t length = 0;
static inline uint32_t
copy_toku_blob(uchar* to_ptr, uchar* from_ptr, uint32_t len_bytes, bool skip) {
uint32_t length = 0;
if (!skip) {
memcpy(to_ptr, from_ptr, len_bytes);
}
......@@ -168,13 +168,13 @@ tokudb_update_fun(
void *set_extra
)
{
u_int32_t max_num_bytes;
u_int32_t num_columns;
uint32_t max_num_bytes;
uint32_t num_columns;
DBT new_val;
u_int32_t num_bytes_left;
u_int32_t num_var_fields_to_copy;
u_int32_t num_data_bytes_written = 0;
u_int32_t num_offset_bytes_written = 0;
uint32_t num_bytes_left;
uint32_t num_var_fields_to_copy;
uint32_t num_data_bytes_written = 0;
uint32_t num_offset_bytes_written = 0;
int error;
memset(&new_val, 0, sizeof(DBT));
uchar operation;
......@@ -184,32 +184,32 @@ tokudb_update_fun(
//
// info for pointers into rows
//
u_int32_t old_num_null_bytes;
u_int32_t new_num_null_bytes;
uint32_t old_num_null_bytes;
uint32_t new_num_null_bytes;
uchar old_num_offset_bytes;
uchar new_num_offset_bytes;
u_int32_t old_fixed_field_size;
u_int32_t new_fixed_field_size;
u_int32_t old_len_of_offsets;
u_int32_t new_len_of_offsets;
uint32_t old_fixed_field_size;
uint32_t new_fixed_field_size;
uint32_t old_len_of_offsets;
uint32_t new_len_of_offsets;
uchar* old_fixed_field_ptr = NULL;
uchar* new_fixed_field_ptr = NULL;
u_int32_t curr_old_fixed_offset;
u_int32_t curr_new_fixed_offset;
uint32_t curr_old_fixed_offset;
uint32_t curr_new_fixed_offset;
uchar* old_null_bytes = NULL;
uchar* new_null_bytes = NULL;
u_int32_t curr_old_null_pos;
u_int32_t curr_new_null_pos;
u_int32_t old_null_bits_left;
u_int32_t new_null_bits_left;
u_int32_t overall_null_bits_left;
u_int32_t old_num_var_fields;
u_int32_t new_num_var_fields;
u_int32_t curr_old_num_var_field;
u_int32_t curr_new_num_var_field;
uint32_t curr_old_null_pos;
uint32_t curr_new_null_pos;
uint32_t old_null_bits_left;
uint32_t new_null_bits_left;
uint32_t overall_null_bits_left;
uint32_t old_num_var_fields;
uint32_t new_num_var_fields;
uint32_t curr_old_num_var_field;
uint32_t curr_new_num_var_field;
uchar* old_var_field_offset_ptr = NULL;
uchar* new_var_field_offset_ptr = NULL;
uchar* curr_new_var_field_offset_ptr = NULL;
......@@ -217,9 +217,9 @@ tokudb_update_fun(
uchar* new_var_field_data_ptr = NULL;
uchar* curr_new_var_field_data_ptr = NULL;
u_int32_t start_blob_offset;
uint32_t start_blob_offset;
uchar* start_blob_ptr;
u_int32_t num_blob_bytes;
uint32_t num_blob_bytes;
// came across a delete, nothing to update
if (old_val == NULL) {
......@@ -234,25 +234,25 @@ tokudb_update_fun(
extra_pos++;
assert(operation == UP_COL_ADD_OR_DROP);
memcpy(&old_num_null_bytes, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
memcpy(&new_num_null_bytes, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
memcpy(&old_num_null_bytes, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
memcpy(&new_num_null_bytes, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
old_num_offset_bytes = extra_pos[0];
extra_pos++;
new_num_offset_bytes = extra_pos[0];
extra_pos++;
memcpy(&old_fixed_field_size, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
memcpy(&new_fixed_field_size, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
memcpy(&old_fixed_field_size, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
memcpy(&new_fixed_field_size, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
memcpy(&old_len_of_offsets, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
memcpy(&new_len_of_offsets, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
memcpy(&old_len_of_offsets, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
memcpy(&new_len_of_offsets, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
max_num_bytes = old_val->size + extra->size + new_len_of_offsets + new_fixed_field_size;
new_val_data = (uchar *)my_malloc(
......@@ -283,10 +283,10 @@ tokudb_update_fun(
new_null_bytes = new_val_data;
memcpy(&curr_old_null_pos, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
memcpy(&curr_new_null_pos, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
memcpy(&curr_old_null_pos, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
memcpy(&curr_new_null_pos, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
memcpy(&num_columns, extra_pos, sizeof(num_columns));
extra_pos += sizeof(num_columns);
......@@ -294,7 +294,7 @@ tokudb_update_fun(
//
// now go through and apply the change into new_val_data
//
for (u_int32_t i = 0; i < num_columns; i++) {
for (uint32_t i = 0; i < num_columns; i++) {
uchar op_type = extra_pos[0];
bool is_null_default = false;
extra_pos++;
......@@ -303,10 +303,10 @@ tokudb_update_fun(
bool nullable = (extra_pos[0] != 0);
extra_pos++;
if (nullable) {
u_int32_t null_bit_position;
memcpy(&null_bit_position, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
u_int32_t num_bits;
uint32_t null_bit_position;
memcpy(&null_bit_position, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
uint32_t num_bits;
if (op_type == COL_DROP) {
assert(curr_old_null_pos <= null_bit_position);
num_bits = null_bit_position - curr_old_null_pos;
......@@ -342,13 +342,13 @@ tokudb_update_fun(
uchar col_type = extra_pos[0];
extra_pos++;
if (col_type == COL_FIXED) {
u_int32_t col_offset;
u_int32_t col_size;
u_int32_t num_bytes_to_copy;
memcpy(&col_offset, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
memcpy(&col_size, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
uint32_t col_offset;
uint32_t col_size;
uint32_t num_bytes_to_copy;
memcpy(&col_offset, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
memcpy(&col_size, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
if (op_type == COL_DROP) {
num_bytes_to_copy = col_offset - curr_old_fixed_offset;
......@@ -386,9 +386,9 @@ tokudb_update_fun(
}
else if (col_type == COL_VAR) {
u_int32_t var_col_index;
memcpy(&var_col_index, extra_pos, sizeof(u_int32_t));
extra_pos += sizeof(u_int32_t);
uint32_t var_col_index;
memcpy(&var_col_index, extra_pos, sizeof(uint32_t));
extra_pos += sizeof(uint32_t);
if (op_type == COL_DROP) {
num_var_fields_to_copy = var_col_index - curr_old_num_var_field;
}
......@@ -428,7 +428,7 @@ tokudb_update_fun(
curr_new_var_field_offset_ptr += new_num_offset_bytes;
}
else {
u_int32_t data_length;
uint32_t data_length;
memcpy(&data_length, extra_pos, sizeof(data_length));
extra_pos += sizeof(data_length);
curr_new_var_field_data_ptr = write_var_field(
......@@ -514,9 +514,9 @@ tokudb_update_fun(
// else, there is blob information to process
else {
uchar* len_bytes = NULL;
u_int32_t curr_old_blob = 0;
u_int32_t curr_new_blob = 0;
u_int32_t num_old_blobs = 0;
uint32_t curr_old_blob = 0;
uint32_t curr_new_blob = 0;
uint32_t num_old_blobs = 0;
uchar* curr_old_blob_ptr = start_blob_ptr;
memcpy(&num_old_blobs, extra_pos, sizeof(num_old_blobs));
extra_pos += sizeof(num_old_blobs);
......@@ -526,8 +526,8 @@ tokudb_update_fun(
while ((extra_pos - extra_pos_start) < extra->size) {
uchar op_type = extra_pos[0];
extra_pos++;
u_int32_t num_blobs_to_copy = 0;
u_int32_t blob_index;
uint32_t num_blobs_to_copy = 0;
uint32_t blob_index;
memcpy(&blob_index, extra_pos, sizeof(blob_index));
extra_pos += sizeof(blob_index);
assert (op_type == COL_DROP || op_type == COL_ADD);
......@@ -537,8 +537,8 @@ tokudb_update_fun(
else {
num_blobs_to_copy = blob_index - curr_new_blob;
}
for (u_int32_t i = 0; i < num_blobs_to_copy; i++) {
u_int32_t num_bytes_written = copy_toku_blob(
for (uint32_t i = 0; i < num_blobs_to_copy; i++) {
uint32_t num_bytes_written = copy_toku_blob(
curr_new_var_field_data_ptr,
curr_old_blob_ptr,
len_bytes[curr_old_blob + i],
......@@ -551,7 +551,7 @@ tokudb_update_fun(
curr_new_blob += num_blobs_to_copy;
if (op_type == COL_DROP) {
// skip over blob in row
u_int32_t num_bytes = copy_toku_blob(
uint32_t num_bytes = copy_toku_blob(
NULL,
curr_old_blob_ptr,
len_bytes[curr_old_blob],
......@@ -562,9 +562,9 @@ tokudb_update_fun(
}
else {
// copy new data
u_int32_t new_len_bytes = extra_pos[0];
uint32_t new_len_bytes = extra_pos[0];
extra_pos++;
u_int32_t num_bytes = copy_toku_blob(
uint32_t num_bytes = copy_toku_blob(
curr_new_var_field_data_ptr,
extra_pos,
new_len_bytes,
......
......@@ -5,15 +5,15 @@
#endif
void get_var_field_info(
u_int32_t* field_len, // output: length of field
u_int32_t* start_offset, // output, length of offset where data starts
u_int32_t var_field_index, //input, index of var field we want info on
uint32_t* field_len, // output: length of field
uint32_t* start_offset, // output, length of offset where data starts
uint32_t var_field_index, //input, index of var field we want info on
const uchar* var_field_offset_ptr, //input, pointer to where offset information for all var fields begins
u_int32_t num_offset_bytes //input, number of bytes used to store offsets starting at var_field_offset_ptr
uint32_t num_offset_bytes //input, number of bytes used to store offsets starting at var_field_offset_ptr
)
{
u_int32_t data_start_offset = 0;
u_int32_t data_end_offset = 0;
uint32_t data_start_offset = 0;
uint32_t data_end_offset = 0;
switch (num_offset_bytes) {
case (1):
data_end_offset = (var_field_offset_ptr + var_field_index)[0];
......@@ -49,13 +49,13 @@ void get_var_field_info(
}
void get_blob_field_info(
u_int32_t* start_offset,
u_int32_t len_of_offsets,
uint32_t* start_offset,
uint32_t len_of_offsets,
const uchar* var_field_data_ptr,
u_int32_t num_offset_bytes
uint32_t num_offset_bytes
)
{
u_int32_t data_end_offset;
uint32_t data_end_offset;
//
// need to set var_field_data_ptr to point to beginning of blobs, which
// is at the end of the var stuff (if they exist), if var stuff does not exist
......@@ -157,7 +157,7 @@ TOKU_TYPE mysql_to_toku_type (Field* field) {
}
static inline CHARSET_INFO* get_charset_from_num (u_int32_t charset_number) {
static inline CHARSET_INFO* get_charset_from_num (uint32_t charset_number) {
//
// patternmatched off of InnoDB, due to MySQL bug 42649
//
......@@ -177,10 +177,10 @@ static inline CHARSET_INFO* get_charset_from_num (u_int32_t charset_number) {
//
// used to read the length of a variable sized field in a tokudb key (buf).
//
static inline u_int32_t get_length_from_var_tokudata (uchar* buf, u_int32_t length_bytes) {
u_int32_t length = (u_int32_t)(buf[0]);
static inline uint32_t get_length_from_var_tokudata (uchar* buf, uint32_t length_bytes) {
uint32_t length = (uint32_t)(buf[0]);
if (length_bytes == 2) {
u_int32_t rest_of_length = (u_int32_t)buf[1];
uint32_t rest_of_length = (uint32_t)buf[1];
length += rest_of_length<<8;
}
return length;
......@@ -190,7 +190,7 @@ static inline u_int32_t get_length_from_var_tokudata (uchar* buf, u_int32_t leng
// used to deduce the number of bytes used to store the length of a varstring/varbinary
// in a key field stored in tokudb
//
static inline u_int32_t get_length_bytes_from_max(u_int32_t max_num_bytes) {
static inline uint32_t get_length_bytes_from_max(uint32_t max_num_bytes) {
return (max_num_bytes > 255) ? 2 : 1;
}
......@@ -199,7 +199,7 @@ static inline u_int32_t get_length_bytes_from_max(u_int32_t max_num_bytes) {
//
// assuming MySQL in little endian, and we are storing in little endian
//
static inline uchar* pack_toku_int (uchar* to_tokudb, uchar* from_mysql, u_int32_t num_bytes) {
static inline uchar* pack_toku_int (uchar* to_tokudb, uchar* from_mysql, uint32_t num_bytes) {
switch (num_bytes) {
case (1):
memcpy(to_tokudb, from_mysql, 1);
......@@ -225,7 +225,7 @@ static inline uchar* pack_toku_int (uchar* to_tokudb, uchar* from_mysql, u_int32
//
// assuming MySQL in little endian, and we are unpacking to little endian
//
static inline uchar* unpack_toku_int(uchar* to_mysql, uchar* from_tokudb, u_int32_t num_bytes) {
static inline uchar* unpack_toku_int(uchar* to_mysql, uchar* from_tokudb, uint32_t num_bytes) {
switch (num_bytes) {
case (1):
memcpy(to_mysql, from_tokudb, 1);
......@@ -248,14 +248,14 @@ static inline uchar* unpack_toku_int(uchar* to_mysql, uchar* from_tokudb, u_int3
return from_tokudb+num_bytes;
}
static inline int cmp_toku_int (uchar* a_buf, uchar* b_buf, bool is_unsigned, u_int32_t num_bytes) {
static inline int cmp_toku_int (uchar* a_buf, uchar* b_buf, bool is_unsigned, uint32_t num_bytes) {
int ret_val = 0;
//
// case for unsigned integers
//
if (is_unsigned) {
u_int32_t a_num, b_num = 0;
u_int64_t a_big_num, b_big_num = 0;
uint32_t a_num, b_num = 0;
uint64_t a_big_num, b_big_num = 0;
switch (num_bytes) {
case (1):
a_num = *a_buf;
......@@ -419,12 +419,12 @@ static inline int cmp_toku_float(uchar* a_buf, uchar* b_buf) {
}
static inline uchar* pack_toku_binary(uchar* to_tokudb, uchar* from_mysql, u_int32_t num_bytes) {
static inline uchar* pack_toku_binary(uchar* to_tokudb, uchar* from_mysql, uint32_t num_bytes) {
memcpy(to_tokudb, from_mysql, num_bytes);
return to_tokudb + num_bytes;
}
static inline uchar* unpack_toku_binary(uchar* to_mysql, uchar* from_tokudb, u_int32_t num_bytes) {
static inline uchar* unpack_toku_binary(uchar* to_mysql, uchar* from_tokudb, uint32_t num_bytes) {
memcpy(to_mysql, from_tokudb, num_bytes);
return from_tokudb + num_bytes;
}
......@@ -432,13 +432,13 @@ static inline uchar* unpack_toku_binary(uchar* to_mysql, uchar* from_tokudb, u_i
static inline int cmp_toku_binary(
uchar* a_buf,
u_int32_t a_num_bytes,
uint32_t a_num_bytes,
uchar* b_buf,
u_int32_t b_num_bytes
uint32_t b_num_bytes
)
{
int ret_val = 0;
u_int32_t num_bytes_to_cmp = (a_num_bytes < b_num_bytes) ? a_num_bytes : b_num_bytes;
uint32_t num_bytes_to_cmp = (a_num_bytes < b_num_bytes) ? a_num_bytes : b_num_bytes;
ret_val = memcmp(a_buf, b_buf, num_bytes_to_cmp);
if ((ret_val != 0) || (a_num_bytes == b_num_bytes)) {
goto exit;
......@@ -461,12 +461,12 @@ static inline int cmp_toku_binary(
uchar* pack_toku_varbinary_from_desc(
uchar* to_tokudb,
const uchar* from_desc,
u_int32_t key_part_length, //number of bytes to use to encode the length in to_tokudb
u_int32_t field_length //length of field
uint32_t key_part_length, //number of bytes to use to encode the length in to_tokudb
uint32_t field_length //length of field
)
{
u_int32_t length_bytes_in_tokudb = get_length_bytes_from_max(key_part_length);
u_int32_t length = field_length;
uint32_t length_bytes_in_tokudb = get_length_bytes_from_max(key_part_length);
uint32_t length = field_length;
set_if_smaller(length, key_part_length);
//
......@@ -486,18 +486,18 @@ uchar* pack_toku_varbinary_from_desc(
static inline uchar* pack_toku_varbinary(
uchar* to_tokudb,
uchar* from_mysql,
u_int32_t length_bytes_in_mysql, //number of bytes used to encode the length in from_mysql
u_int32_t max_num_bytes
uint32_t length_bytes_in_mysql, //number of bytes used to encode the length in from_mysql
uint32_t max_num_bytes
)
{
u_int32_t length = 0;
u_int32_t length_bytes_in_tokudb;
uint32_t length = 0;
uint32_t length_bytes_in_tokudb;
switch (length_bytes_in_mysql) {
case (0):
length = max_num_bytes;
break;
case (1):
length = (u_int32_t)(*from_mysql);
length = (uint32_t)(*from_mysql);
break;
case (2):
length = uint2korr(from_mysql);
......@@ -533,11 +533,11 @@ static inline uchar* pack_toku_varbinary(
static inline uchar* unpack_toku_varbinary(
uchar* to_mysql,
uchar* from_tokudb,
u_int32_t length_bytes_in_tokudb, // number of bytes used to encode length in from_tokudb
u_int32_t length_bytes_in_mysql // number of bytes used to encode length in to_mysql
uint32_t length_bytes_in_tokudb, // number of bytes used to encode length in from_tokudb
uint32_t length_bytes_in_mysql // number of bytes used to encode length in to_mysql
)
{
u_int32_t length = get_length_from_var_tokudata(from_tokudb, length_bytes_in_tokudb);
uint32_t length = get_length_from_var_tokudata(from_tokudb, length_bytes_in_tokudb);
//
// copy the length into the mysql buffer
......@@ -570,14 +570,14 @@ static inline uchar* unpack_toku_varbinary(
static inline int cmp_toku_varbinary(
uchar* a_buf,
uchar* b_buf,
u_int32_t length_bytes, //number of bytes used to encode length in a_buf and b_buf
u_int32_t* a_bytes_read,
u_int32_t* b_bytes_read
uint32_t length_bytes, //number of bytes used to encode length in a_buf and b_buf
uint32_t* a_bytes_read,
uint32_t* b_bytes_read
)
{
int ret_val = 0;
u_int32_t a_len = get_length_from_var_tokudata(a_buf, length_bytes);
u_int32_t b_len = get_length_from_var_tokudata(b_buf, length_bytes);
uint32_t a_len = get_length_from_var_tokudata(a_buf, length_bytes);
uint32_t b_len = get_length_from_var_tokudata(b_buf, length_bytes);
ret_val = cmp_toku_binary(
a_buf + length_bytes,
a_len,
......@@ -592,9 +592,9 @@ static inline int cmp_toku_varbinary(
static inline uchar* pack_toku_blob(
uchar* to_tokudb,
uchar* from_mysql,
u_int32_t length_bytes_in_tokudb, //number of bytes to use to encode the length in to_tokudb
u_int32_t length_bytes_in_mysql, //number of bytes used to encode the length in from_mysql
u_int32_t max_num_bytes,
uint32_t length_bytes_in_tokudb, //number of bytes to use to encode the length in to_tokudb
uint32_t length_bytes_in_mysql, //number of bytes used to encode the length in from_mysql
uint32_t max_num_bytes,
#if MYSQL_VERSION_ID >= 50600
const CHARSET_INFO* charset
#else
......@@ -602,8 +602,8 @@ static inline uchar* pack_toku_blob(
#endif
)
{
u_int32_t length = 0;
u_int32_t local_char_length = 0;
uint32_t length = 0;
uint32_t local_char_length = 0;
uchar* blob_buf = NULL;
switch (length_bytes_in_mysql) {
......@@ -611,7 +611,7 @@ static inline uchar* pack_toku_blob(
length = max_num_bytes;
break;
case (1):
length = (u_int32_t)(*from_mysql);
length = (uint32_t)(*from_mysql);
break;
case (2):
length = uint2korr(from_mysql);
......@@ -659,11 +659,11 @@ static inline uchar* pack_toku_blob(
static inline uchar* unpack_toku_blob(
uchar* to_mysql,
uchar* from_tokudb,
u_int32_t length_bytes_in_tokudb, // number of bytes used to encode length in from_tokudb
u_int32_t length_bytes_in_mysql // number of bytes used to encode length in to_mysql
uint32_t length_bytes_in_tokudb, // number of bytes used to encode length in from_tokudb
uint32_t length_bytes_in_mysql // number of bytes used to encode length in to_mysql
)
{
u_int32_t length = get_length_from_var_tokudata(from_tokudb, length_bytes_in_tokudb);
uint32_t length = get_length_from_var_tokudata(from_tokudb, length_bytes_in_tokudb);
uchar* blob_pos = NULL;
//
// copy the length into the mysql buffer
......@@ -701,15 +701,15 @@ static inline uchar* unpack_toku_blob(
uchar* pack_toku_varstring_from_desc(
uchar* to_tokudb,
const uchar* from_desc,
u_int32_t key_part_length, //number of bytes to use to encode the length in to_tokudb
u_int32_t field_length,
u_int32_t charset_num//length of field
uint32_t key_part_length, //number of bytes to use to encode the length in to_tokudb
uint32_t field_length,
uint32_t charset_num//length of field
)
{
CHARSET_INFO* charset = NULL;
u_int32_t length_bytes_in_tokudb = get_length_bytes_from_max(key_part_length);
u_int32_t length = field_length;
u_int32_t local_char_length = 0;
uint32_t length_bytes_in_tokudb = get_length_bytes_from_max(key_part_length);
uint32_t length = field_length;
uint32_t local_char_length = 0;
set_if_smaller(length, key_part_length);
charset = get_charset_from_num(charset_num);
......@@ -748,9 +748,9 @@ uchar* pack_toku_varstring_from_desc(
static inline uchar* pack_toku_varstring(
uchar* to_tokudb,
uchar* from_mysql,
u_int32_t length_bytes_in_tokudb, //number of bytes to use to encode the length in to_tokudb
u_int32_t length_bytes_in_mysql, //number of bytes used to encode the length in from_mysql
u_int32_t max_num_bytes,
uint32_t length_bytes_in_tokudb, //number of bytes to use to encode the length in to_tokudb
uint32_t length_bytes_in_mysql, //number of bytes used to encode the length in from_mysql
uint32_t max_num_bytes,
#if MYSQL_VERSION_ID >= 50600
const CHARSET_INFO *charset
#else
......@@ -758,15 +758,15 @@ static inline uchar* pack_toku_varstring(
#endif
)
{
u_int32_t length = 0;
u_int32_t local_char_length = 0;
uint32_t length = 0;
uint32_t local_char_length = 0;
switch (length_bytes_in_mysql) {
case (0):
length = max_num_bytes;
break;
case (1):
length = (u_int32_t)(*from_mysql);
length = (uint32_t)(*from_mysql);
break;
case (2):
length = uint2korr(from_mysql);
......@@ -810,10 +810,10 @@ static inline uchar* pack_toku_varstring(
static inline int cmp_toku_string(
uchar* a_buf,
u_int32_t a_num_bytes,
uint32_t a_num_bytes,
uchar* b_buf,
u_int32_t b_num_bytes,
u_int32_t charset_number
uint32_t b_num_bytes,
uint32_t charset_number
)
{
int ret_val = 0;
......@@ -835,15 +835,15 @@ static inline int cmp_toku_string(
static inline int cmp_toku_varstring(
uchar* a_buf,
uchar* b_buf,
u_int32_t length_bytes, //number of bytes used to encode length in a_buf and b_buf
u_int32_t charset_num,
u_int32_t* a_bytes_read,
u_int32_t* b_bytes_read
uint32_t length_bytes, //number of bytes used to encode length in a_buf and b_buf
uint32_t charset_num,
uint32_t* a_bytes_read,
uint32_t* b_bytes_read
)
{
int ret_val = 0;
u_int32_t a_len = get_length_from_var_tokudata(a_buf, length_bytes);
u_int32_t b_len = get_length_from_var_tokudata(b_buf, length_bytes);
uint32_t a_len = get_length_from_var_tokudata(a_buf, length_bytes);
uint32_t b_len = get_length_from_var_tokudata(b_buf, length_bytes);
ret_val = cmp_toku_string(
a_buf + length_bytes,
a_len,
......@@ -858,9 +858,9 @@ static inline int cmp_toku_varstring(
static inline int tokudb_compare_two_hidden_keys(
const void* new_key_data,
const u_int32_t new_key_size,
const uint32_t new_key_size,
const void* saved_key_data,
const u_int32_t saved_key_size
const uint32_t saved_key_size
) {
assert( (new_key_size >= TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH) && (saved_key_size >= TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH) );
ulonglong a = hpk_char_to_num((uchar *) new_key_data);
......@@ -878,7 +878,7 @@ static inline int tokudb_compare_two_hidden_keys(
// created in create_toku_key_descriptor_for_key. The first
// byte points to the TOKU_TYPE.
//
u_int32_t skip_field_in_descriptor(uchar* row_desc) {
uint32_t skip_field_in_descriptor(uchar* row_desc) {
uchar* row_desc_pos = row_desc;
TOKU_TYPE toku_type = (TOKU_TYPE)row_desc_pos[0];
row_desc_pos++;
......@@ -899,13 +899,13 @@ u_int32_t skip_field_in_descriptor(uchar* row_desc) {
case (toku_type_varstring):
case (toku_type_blob):
row_desc_pos++;
row_desc_pos += sizeof(u_int32_t);
row_desc_pos += sizeof(uint32_t);
break;
default:
assert(false);
break;
}
return (u_int32_t)(row_desc_pos - row_desc);
return (uint32_t)(row_desc_pos - row_desc);
}
//
......@@ -915,8 +915,8 @@ u_int32_t skip_field_in_descriptor(uchar* row_desc) {
//
int create_toku_key_descriptor_for_key(KEY* key, uchar* buf) {
uchar* pos = buf;
u_int32_t num_bytes_in_field = 0;
u_int32_t charset_num = 0;
uint32_t num_bytes_in_field = 0;
uint32_t charset_num = 0;
for (uint i = 0; i < key->key_parts; i++){
Field* field = key->key_part[i].field;
//
......@@ -1031,8 +1031,8 @@ int create_toku_key_descriptor(
// ends.
//
uchar* pos = buf + 4;
u_int32_t num_bytes = 0;
u_int32_t offset = 0;
uint32_t num_bytes = 0;
uint32_t offset = 0;
if (is_first_hpk) {
......@@ -1093,16 +1093,16 @@ static inline int compare_toku_field(
uchar* a_buf,
uchar* b_buf,
uchar* row_desc,
u_int32_t* a_bytes_read,
u_int32_t* b_bytes_read,
u_int32_t* row_desc_bytes_read
uint32_t* a_bytes_read,
uint32_t* b_bytes_read,
uint32_t* row_desc_bytes_read
)
{
int ret_val = 0;
uchar* row_desc_pos = row_desc;
u_int32_t num_bytes = 0;
u_int32_t length_bytes = 0;
u_int32_t charset_num = 0;
uint32_t num_bytes = 0;
uint32_t length_bytes = 0;
uint32_t charset_num = 0;
bool is_unsigned = false;
TOKU_TYPE toku_type = (TOKU_TYPE)row_desc_pos[0];
......@@ -1168,8 +1168,8 @@ static inline int compare_toku_field(
//
// not sure we want to read charset_num like this
//
charset_num = *(u_int32_t *)row_desc_pos;
row_desc_pos += sizeof(u_int32_t);
charset_num = *(uint32_t *)row_desc_pos;
row_desc_pos += sizeof(uint32_t);
ret_val = cmp_toku_varstring(
a_buf,
b_buf,
......@@ -1196,11 +1196,11 @@ uchar* pack_toku_key_field(
uchar* to_tokudb,
uchar* from_mysql,
Field* field,
u_int32_t key_part_length //I really hope this is temporary as I phase out the pack_cmp stuff
uint32_t key_part_length //I really hope this is temporary as I phase out the pack_cmp stuff
)
{
uchar* new_pos = NULL;
u_int32_t num_bytes = 0;
uint32_t num_bytes = 0;
TOKU_TYPE toku_type = mysql_to_toku_type(field);
switch(toku_type) {
case (toku_type_int):
......@@ -1289,7 +1289,7 @@ uchar* pack_key_toku_key_field(
uchar* to_tokudb,
uchar* from_mysql,
Field* field,
u_int32_t key_part_length //I really hope this is temporary as I phase out the pack_cmp stuff
uint32_t key_part_length //I really hope this is temporary as I phase out the pack_cmp stuff
)
{
uchar* new_pos = NULL;
......@@ -1335,12 +1335,12 @@ uchar* unpack_toku_key_field(
uchar* to_mysql,
uchar* from_tokudb,
Field* field,
u_int32_t key_part_length
uint32_t key_part_length
)
{
uchar* new_pos = NULL;
u_int32_t num_bytes = 0;
u_int32_t num_bytes_copied;
uint32_t num_bytes = 0;
uint32_t num_bytes_copied;
TOKU_TYPE toku_type = mysql_to_toku_type(field);
switch(toku_type) {
case (toku_type_int):
......@@ -1410,11 +1410,11 @@ uchar* unpack_toku_key_field(
int tokudb_compare_two_keys(
const void* new_key_data,
const u_int32_t new_key_size,
const uint32_t new_key_size,
const void* saved_key_data,
const u_int32_t saved_key_size,
const uint32_t saved_key_size,
const void* row_desc,
const u_int32_t row_desc_size,
const uint32_t row_desc_size,
bool cmp_prefix
)
{
......@@ -1426,8 +1426,8 @@ int tokudb_compare_two_keys(
uchar *new_key_ptr = (uchar *)new_key_data;
uchar *saved_key_ptr = (uchar *)saved_key_data;
u_int32_t new_key_bytes_left = new_key_size;
u_int32_t saved_key_bytes_left = saved_key_size;
uint32_t new_key_bytes_left = new_key_size;
uint32_t saved_key_bytes_left = saved_key_size;
//
// if the keys have an infinity byte, set it
......@@ -1440,14 +1440,14 @@ int tokudb_compare_two_keys(
}
row_desc_ptr++;
while ( (u_int32_t)(new_key_ptr - (uchar *)new_key_data) < new_key_size &&
(u_int32_t)(saved_key_ptr - (uchar *)saved_key_data) < saved_key_size &&
(u_int32_t)(row_desc_ptr - (uchar *)row_desc) < row_desc_size
while ( (uint32_t)(new_key_ptr - (uchar *)new_key_data) < new_key_size &&
(uint32_t)(saved_key_ptr - (uchar *)saved_key_data) < saved_key_size &&
(uint32_t)(row_desc_ptr - (uchar *)row_desc) < row_desc_size
)
{
u_int32_t new_key_field_length;
u_int32_t saved_key_field_length;
u_int32_t row_desc_field_length;
uint32_t new_key_field_length;
uint32_t saved_key_field_length;
uint32_t row_desc_field_length;
//
// if there is a null byte at this point in the key
//
......@@ -1493,12 +1493,12 @@ int tokudb_compare_two_keys(
goto exit;
}
assert((u_int32_t)(new_key_ptr - (uchar *)new_key_data) <= new_key_size);
assert((u_int32_t)(saved_key_ptr - (uchar *)saved_key_data) <= saved_key_size);
assert((u_int32_t)(row_desc_ptr - (uchar *)row_desc) <= row_desc_size);
assert((uint32_t)(new_key_ptr - (uchar *)new_key_data) <= new_key_size);
assert((uint32_t)(saved_key_ptr - (uchar *)saved_key_data) <= saved_key_size);
assert((uint32_t)(row_desc_ptr - (uchar *)row_desc) <= row_desc_size);
}
new_key_bytes_left = new_key_size - ((u_int32_t)(new_key_ptr - (uchar *)new_key_data));
saved_key_bytes_left = saved_key_size - ((u_int32_t)(saved_key_ptr - (uchar *)saved_key_data));
new_key_bytes_left = new_key_size - ((uint32_t)(new_key_ptr - (uchar *)new_key_data));
saved_key_bytes_left = saved_key_size - ((uint32_t)(saved_key_ptr - (uchar *)saved_key_data));
if (cmp_prefix) {
ret_val = 0;
}
......@@ -1545,7 +1545,7 @@ int tokudb_cmp_dbt_key(DB* file, const DBT *keya, const DBT *keyb) {
keyb->data,
keyb->size,
(uchar *)file->cmp_descriptor->dbt.data + 4,
(*(u_int32_t *)file->cmp_descriptor->dbt.data) - 4,
(*(uint32_t *)file->cmp_descriptor->dbt.data) - 4,
false
);
}
......@@ -1560,14 +1560,14 @@ int tokudb_prefix_cmp_dbt_key(DB *file, const DBT *keya, const DBT *keyb) {
keyb->data,
keyb->size,
(uchar *)file->cmp_descriptor->dbt.data + 4,
*(u_int32_t *)file->cmp_descriptor->dbt.data - 4,
*(uint32_t *)file->cmp_descriptor->dbt.data - 4,
true
);
return cmp;
}
u_int32_t create_toku_main_key_pack_descriptor (
uint32_t create_toku_main_key_pack_descriptor (
uchar* buf
)
{
......@@ -1576,7 +1576,7 @@ u_int32_t create_toku_main_key_pack_descriptor (
// ends.
//
uchar* pos = buf + 4;
u_int32_t offset = 0;
uint32_t offset = 0;
//
// one byte states if this is the main dictionary
//
......@@ -1611,18 +1611,18 @@ u_int32_t create_toku_main_key_pack_descriptor (
#define COPY_OFFSET_TO_BUF memcpy ( \
pos, \
&kc_info->cp_info[pk_index][field_index].col_pack_val, \
sizeof(u_int32_t) \
sizeof(uint32_t) \
); \
pos += sizeof(u_int32_t);
pos += sizeof(uint32_t);
u_int32_t pack_desc_pk_info(uchar* buf, KEY_AND_COL_INFO* kc_info, TABLE_SHARE* table_share, KEY_PART_INFO* key_part) {
uint32_t pack_desc_pk_info(uchar* buf, KEY_AND_COL_INFO* kc_info, TABLE_SHARE* table_share, KEY_PART_INFO* key_part) {
uchar* pos = buf;
uint16 field_index = key_part->field->field_index;
Field* field = table_share->field[field_index];
TOKU_TYPE toku_type = mysql_to_toku_type(field);
u_int32_t key_part_length = key_part->length;
u_int32_t field_length;
uint32_t key_part_length = key_part->length;
uint32_t field_length;
uchar len_bytes = 0;
switch(toku_type) {
......@@ -1661,7 +1661,7 @@ u_int32_t pack_desc_pk_info(uchar* buf, KEY_AND_COL_INFO* kc_info, TABLE_SHARE*
return pos - buf;
}
u_int32_t pack_desc_pk_offset_info(
uint32_t pack_desc_pk_offset_info(
uchar* buf,
KEY_AND_COL_INFO* kc_info,
TABLE_SHARE* table_share,
......@@ -1673,10 +1673,10 @@ u_int32_t pack_desc_pk_offset_info(
uchar* pos = buf;
uint16 field_index = key_part->field->field_index;
bool found_col_in_pk = false;
u_int32_t index_in_pk;
uint32_t index_in_pk;
bool is_constant_offset = true;
u_int32_t offset = 0;
uint32_t offset = 0;
for (uint i = 0; i < prim_key->key_parts; i++) {
KEY_PART_INFO curr = prim_key->key_part[i];
uint16 curr_field_index = curr.field->field_index;
......@@ -1710,7 +1710,7 @@ u_int32_t pack_desc_pk_offset_info(
return pos - buf;
}
u_int32_t pack_desc_offset_info(uchar* buf, KEY_AND_COL_INFO* kc_info, uint pk_index, TABLE_SHARE* table_share, KEY_PART_INFO* key_part) {
uint32_t pack_desc_offset_info(uchar* buf, KEY_AND_COL_INFO* kc_info, uint pk_index, TABLE_SHARE* table_share, KEY_PART_INFO* key_part) {
uchar* pos = buf;
uint16 field_index = key_part->field->field_index;
Field* field = table_share->field[field_index];
......@@ -1740,12 +1740,12 @@ u_int32_t pack_desc_offset_info(uchar* buf, KEY_AND_COL_INFO* kc_info, uint pk_i
case (toku_type_blob):
pos[0] = COL_BLOB_FIELD;
pos++;
for (u_int32_t i = 0; i < kc_info->num_blobs; i++) {
u_int32_t blob_index = kc_info->blob_fields[i];
for (uint32_t i = 0; i < kc_info->num_blobs; i++) {
uint32_t blob_index = kc_info->blob_fields[i];
if (blob_index == field_index) {
u_int32_t val = i;
memcpy(pos, &val, sizeof(u_int32_t));
pos += sizeof(u_int32_t);
uint32_t val = i;
memcpy(pos, &val, sizeof(uint32_t));
pos += sizeof(uint32_t);
found_index = true;
break;
}
......@@ -1759,13 +1759,13 @@ u_int32_t pack_desc_offset_info(uchar* buf, KEY_AND_COL_INFO* kc_info, uint pk_i
return pos - buf;
}
u_int32_t pack_desc_key_length_info(uchar* buf, KEY_AND_COL_INFO* kc_info, TABLE_SHARE* table_share, KEY_PART_INFO* key_part) {
uint32_t pack_desc_key_length_info(uchar* buf, KEY_AND_COL_INFO* kc_info, TABLE_SHARE* table_share, KEY_PART_INFO* key_part) {
uchar* pos = buf;
uint16 field_index = key_part->field->field_index;
Field* field = table_share->field[field_index];
TOKU_TYPE toku_type = mysql_to_toku_type(field);
u_int32_t key_part_length = key_part->length;
u_int32_t field_length;
uint32_t key_part_length = key_part->length;
uint32_t field_length;
switch(toku_type) {
case (toku_type_int):
......@@ -1794,12 +1794,12 @@ u_int32_t pack_desc_key_length_info(uchar* buf, KEY_AND_COL_INFO* kc_info, TABLE
return pos - buf;
}
u_int32_t pack_desc_char_info(uchar* buf, KEY_AND_COL_INFO* kc_info, TABLE_SHARE* table_share, KEY_PART_INFO* key_part) {
uint32_t pack_desc_char_info(uchar* buf, KEY_AND_COL_INFO* kc_info, TABLE_SHARE* table_share, KEY_PART_INFO* key_part) {
uchar* pos = buf;
uint16 field_index = key_part->field->field_index;
Field* field = table_share->field[field_index];
TOKU_TYPE toku_type = mysql_to_toku_type(field);
u_int32_t charset_num = 0;
uint32_t charset_num = 0;
switch(toku_type) {
case (toku_type_int):
......@@ -1831,7 +1831,7 @@ u_int32_t pack_desc_char_info(uchar* buf, KEY_AND_COL_INFO* kc_info, TABLE_SHARE
return pos - buf;
}
u_int32_t pack_some_row_info (
uint32_t pack_some_row_info (
uchar* buf,
uint pk_index,
TABLE_SHARE* table_share,
......@@ -1839,7 +1839,7 @@ u_int32_t pack_some_row_info (
)
{
uchar* pos = buf;
u_int32_t num_null_bytes = 0;
uint32_t num_null_bytes = 0;
//
// four bytes stating number of null bytes
//
......@@ -1860,17 +1860,17 @@ u_int32_t pack_some_row_info (
return pos - buf;
}
u_int32_t get_max_clustering_val_pack_desc_size(
uint32_t get_max_clustering_val_pack_desc_size(
TABLE_SHARE* table_share
)
{
u_int32_t ret_val = 0;
uint32_t ret_val = 0;
//
// the fixed stuff:
// first the things in pack_some_row_info
// second another mcp_info
// third a byte that states if blobs exist
ret_val += sizeof(u_int32_t) + sizeof(MULTI_COL_PACK_INFO) + 1;
ret_val += sizeof(uint32_t) + sizeof(MULTI_COL_PACK_INFO) + 1;
ret_val += sizeof(MULTI_COL_PACK_INFO);
ret_val++;
//
......@@ -1878,7 +1878,7 @@ u_int32_t get_max_clustering_val_pack_desc_size(
// an upper bound is, for each field, byte stating if it is fixed or var, followed
// by 8 bytes for endpoints
//
ret_val += (table_share->fields)*(1 + 2*sizeof(u_int32_t));
ret_val += (table_share->fields)*(1 + 2*sizeof(uint32_t));
//
// four bytes storing the length of this portion
//
......@@ -1887,19 +1887,19 @@ u_int32_t get_max_clustering_val_pack_desc_size(
return ret_val;
}
u_int32_t create_toku_clustering_val_pack_descriptor (
uint32_t create_toku_clustering_val_pack_descriptor (
uchar* buf,
uint pk_index,
TABLE_SHARE* table_share,
KEY_AND_COL_INFO* kc_info,
u_int32_t keynr,
uint32_t keynr,
bool is_clustering
)
{
uchar* pos = buf + 4;
u_int32_t offset = 0;
uint32_t offset = 0;
bool start_range_set = false;
u_int32_t last_col = 0;
uint32_t last_col = 0;
//
// do not need to write anything if the key is not clustering
//
......@@ -1957,7 +1957,7 @@ u_int32_t create_toku_clustering_val_pack_descriptor (
// need to set the end range
//
start_range_set = false;
u_int32_t end_offset = kc_info->cp_info[pk_index][last_col].col_pack_val + kc_info->field_lengths[last_col];
uint32_t end_offset = kc_info->cp_info[pk_index][last_col].col_pack_val + kc_info->field_lengths[last_col];
memcpy(pos, &end_offset, sizeof(end_offset));
pos += sizeof(end_offset);
}
......@@ -1966,7 +1966,7 @@ u_int32_t create_toku_clustering_val_pack_descriptor (
pos[0] = CK_FIX_RANGE;
pos++;
start_range_set = true;
u_int32_t start_offset = kc_info->cp_info[pk_index][i].col_pack_val;
uint32_t start_offset = kc_info->cp_info[pk_index][i].col_pack_val;
memcpy(pos, &start_offset , sizeof(start_offset));
pos += sizeof(start_offset);
}
......@@ -1981,7 +1981,7 @@ u_int32_t create_toku_clustering_val_pack_descriptor (
// need to set the end range
//
start_range_set = false;
u_int32_t end_offset = kc_info->cp_info[pk_index][last_col].col_pack_val+ kc_info->field_lengths[last_col];
uint32_t end_offset = kc_info->cp_info[pk_index][last_col].col_pack_val+ kc_info->field_lengths[last_col];
memcpy(pos, &end_offset, sizeof(end_offset));
pos += sizeof(end_offset);
}
......@@ -2004,7 +2004,7 @@ u_int32_t create_toku_clustering_val_pack_descriptor (
// need to set the end range
//
start_range_set = false;
u_int32_t end_offset = kc_info->cp_info[pk_index][last_col].col_pack_val;
uint32_t end_offset = kc_info->cp_info[pk_index][last_col].col_pack_val;
memcpy(pos, &end_offset, sizeof(end_offset));
pos += sizeof(end_offset);
}
......@@ -2014,7 +2014,7 @@ u_int32_t create_toku_clustering_val_pack_descriptor (
pos++;
start_range_set = true;
u_int32_t start_offset = kc_info->cp_info[pk_index][i].col_pack_val;
uint32_t start_offset = kc_info->cp_info[pk_index][i].col_pack_val;
memcpy(pos, &start_offset , sizeof(start_offset));
pos += sizeof(start_offset);
}
......@@ -2026,7 +2026,7 @@ u_int32_t create_toku_clustering_val_pack_descriptor (
}
if (start_range_set) {
start_range_set = false;
u_int32_t end_offset = kc_info->cp_info[pk_index][last_col].col_pack_val;
uint32_t end_offset = kc_info->cp_info[pk_index][last_col].col_pack_val;
memcpy(pos, &end_offset, sizeof(end_offset));
pos += sizeof(end_offset);
}
......@@ -2041,10 +2041,10 @@ u_int32_t create_toku_clustering_val_pack_descriptor (
return pos - buf;
}
u_int32_t pack_clustering_val_from_desc(
uint32_t pack_clustering_val_from_desc(
uchar* buf,
void* row_desc,
u_int32_t row_desc_size,
uint32_t row_desc_size,
const DBT* pk_val
)
{
......@@ -2057,8 +2057,8 @@ u_int32_t pack_clustering_val_from_desc(
uchar* var_dest_data_ptr = NULL;
uchar* orig_var_dest_data_ptr = NULL;
uchar* desc_pos = (uchar *)row_desc;
u_int32_t num_null_bytes = 0;
u_int32_t num_offset_bytes;
uint32_t num_null_bytes = 0;
uint32_t num_offset_bytes;
MULTI_COL_PACK_INFO src_mcp_info, dest_mcp_info;
uchar has_blobs;
......@@ -2094,8 +2094,8 @@ u_int32_t pack_clustering_val_from_desc(
// copy the null bytes
//
memcpy(buf, null_bytes_src_ptr, num_null_bytes);
while ( (u_int32_t)(desc_pos - (uchar *)row_desc) < row_desc_size) {
u_int32_t start, end, length;
while ( (uint32_t)(desc_pos - (uchar *)row_desc) < row_desc_size) {
uint32_t start, end, length;
uchar curr = desc_pos[0];
desc_pos++;
......@@ -2114,11 +2114,11 @@ u_int32_t pack_clustering_val_from_desc(
fixed_dest_ptr += length;
}
else if (curr == CK_VAR_RANGE) {
u_int32_t start_data_size;
u_int32_t start_data_offset;
u_int32_t end_data_size;
u_int32_t end_data_offset;
u_int32_t offset_diffs;
uint32_t start_data_size;
uint32_t start_data_offset;
uint32_t end_data_size;
uint32_t end_data_offset;
uint32_t offset_diffs;
get_var_field_info(
&start_data_size,
......@@ -2148,16 +2148,16 @@ u_int32_t pack_clustering_val_from_desc(
//
// put in offset info
//
offset_diffs = (end_data_offset + end_data_size) - (u_int32_t)(var_dest_data_ptr - orig_var_dest_data_ptr);
for (u_int32_t i = start; i <= end; i++) {
offset_diffs = (end_data_offset + end_data_size) - (uint32_t)(var_dest_data_ptr - orig_var_dest_data_ptr);
for (uint32_t i = start; i <= end; i++) {
if ( num_offset_bytes == 1 ) {
assert(offset_diffs < 256);
var_dest_offset_ptr[0] = var_src_offset_ptr[i] - (uchar)offset_diffs;
var_dest_offset_ptr++;
}
else if ( num_offset_bytes == 2 ) {
u_int32_t tmp = uint2korr(var_src_offset_ptr + 2*i);
u_int32_t new_offset = tmp - offset_diffs;
uint32_t tmp = uint2korr(var_src_offset_ptr + 2*i);
uint32_t new_offset = tmp - offset_diffs;
assert(new_offset < 1<<16);
int2store(var_dest_offset_ptr,new_offset);
var_dest_offset_ptr += 2;
......@@ -2177,8 +2177,8 @@ u_int32_t pack_clustering_val_from_desc(
// so, we put the blobs at var_dest_data_ptr
//
if (has_blobs) {
u_int32_t num_blob_bytes;
u_int32_t start_offset;
uint32_t num_blob_bytes;
uint32_t start_offset;
uchar* src_blob_ptr = NULL;
get_blob_field_info(
&start_offset,
......@@ -2195,11 +2195,11 @@ u_int32_t pack_clustering_val_from_desc(
}
u_int32_t get_max_secondary_key_pack_desc_size(
uint32_t get_max_secondary_key_pack_desc_size(
KEY_AND_COL_INFO* kc_info
)
{
u_int32_t ret_val = 0;
uint32_t ret_val = 0;
//
// the fixed stuff:
// byte that states if main dictionary
......@@ -2207,7 +2207,7 @@ u_int32_t get_max_secondary_key_pack_desc_size(
// the things in pack_some_row_info
ret_val++;
ret_val++;
ret_val += sizeof(u_int32_t) + sizeof(MULTI_COL_PACK_INFO) + 1;
ret_val += sizeof(uint32_t) + sizeof(MULTI_COL_PACK_INFO) + 1;
//
// now variable sized stuff
//
......@@ -2226,7 +2226,7 @@ u_int32_t get_max_secondary_key_pack_desc_size(
// null bit, then null byte,
// then 1 byte stating what it is, then 4 for offset, 4 for key length,
// 1 for if charset exists, and 4 for charset
ret_val += MAX_REF_PARTS*(1 + sizeof(u_int32_t) + 1 + 3*sizeof(u_int32_t) + 1);
ret_val += MAX_REF_PARTS*(1 + sizeof(uint32_t) + 1 + 3*sizeof(uint32_t) + 1);
//
// four bytes storing the length of this portion
//
......@@ -2234,7 +2234,7 @@ u_int32_t get_max_secondary_key_pack_desc_size(
return ret_val;
}
u_int32_t create_toku_secondary_key_pack_descriptor (
uint32_t create_toku_secondary_key_pack_descriptor (
uchar* buf,
bool has_hpk,
uint pk_index,
......@@ -2251,7 +2251,7 @@ u_int32_t create_toku_secondary_key_pack_descriptor (
//
uchar* pk_info = NULL;
uchar* pos = buf + 4;
u_int32_t offset = 0;
uint32_t offset = 0;
//
// first byte states that it is NOT main dictionary
......@@ -2281,8 +2281,8 @@ u_int32_t create_toku_secondary_key_pack_descriptor (
// store blob information
//
memcpy(pos, &kc_info->num_blobs, sizeof(kc_info->num_blobs));
pos += sizeof(u_int32_t);
for (u_int32_t i = 0; i < kc_info->num_blobs; i++) {
pos += sizeof(uint32_t);
for (uint32_t i = 0; i < kc_info->num_blobs; i++) {
//
// store length bytes for each blob
//
......@@ -2354,9 +2354,9 @@ u_int32_t create_toku_secondary_key_pack_descriptor (
}
if (field->null_bit) {
u_int32_t null_offset = get_null_offset(table,table->field[field_index]);
memcpy(pos, &null_offset, sizeof(u_int32_t));
pos += sizeof(u_int32_t);
uint32_t null_offset = get_null_offset(table,table->field[field_index]);
memcpy(pos, &null_offset, sizeof(uint32_t));
pos += sizeof(uint32_t);
}
if (is_col_in_pk) {
pos += pack_desc_pk_offset_info(
......@@ -2400,7 +2400,7 @@ u_int32_t create_toku_secondary_key_pack_descriptor (
return pos - buf;
}
u_int32_t skip_key_in_desc(
uint32_t skip_key_in_desc(
uchar* row_desc
)
{
......@@ -2414,12 +2414,12 @@ u_int32_t skip_key_in_desc(
//
// skip the offset information
//
pos += sizeof(u_int32_t);
pos += sizeof(uint32_t);
//
// skip the key_part_length info
//
pos += sizeof(u_int32_t);
pos += sizeof(uint32_t);
col_bin_or_char = pos[0];
pos++;
if (col_bin_or_char == COL_HAS_NO_CHARSET) {
......@@ -2432,22 +2432,22 @@ u_int32_t skip_key_in_desc(
exit:
return (u_int32_t)(pos-row_desc);
return (uint32_t)(pos-row_desc);
}
u_int32_t max_key_size_from_desc(
uint32_t max_key_size_from_desc(
void* row_desc,
u_int32_t row_desc_size
uint32_t row_desc_size
)
{
uchar* desc_pos = (uchar *)row_desc;
u_int32_t num_blobs;
u_int32_t num_pk_columns;
uint32_t num_blobs;
uint32_t num_pk_columns;
//
// start at 1 for the infinity byte
//
u_int32_t max_size = 1;
uint32_t max_size = 1;
// skip byte that states if main dictionary
bool is_main_dictionary = desc_pos[0];
......@@ -2458,7 +2458,7 @@ u_int32_t max_key_size_from_desc(
desc_pos++;
// skip num_null_bytes
desc_pos += sizeof(u_int32_t);
desc_pos += sizeof(uint32_t);
// skip mcp_info
desc_pos += sizeof(MULTI_COL_PACK_INFO);
......@@ -2476,9 +2476,9 @@ u_int32_t max_key_size_from_desc(
desc_pos++;
desc_pos += 2*num_pk_columns;
while ( (u_int32_t)(desc_pos - (uchar *)row_desc) < row_desc_size) {
while ( (uint32_t)(desc_pos - (uchar *)row_desc) < row_desc_size) {
uchar has_charset;
u_int32_t key_length = 0;
uint32_t key_length = 0;
uchar null_bit = desc_pos[0];
desc_pos++;
......@@ -2488,7 +2488,7 @@ u_int32_t max_key_size_from_desc(
// column is NULLable, skip null_offset, and add a null byte
//
max_size++;
desc_pos += sizeof(u_int32_t);
desc_pos += sizeof(uint32_t);
}
//
// skip over byte that states if fix or var
......@@ -2496,7 +2496,7 @@ u_int32_t max_key_size_from_desc(
desc_pos++;
// skip over offset
desc_pos += sizeof(u_int32_t);
desc_pos += sizeof(uint32_t);
//
// get the key length and add it to return value
......@@ -2509,7 +2509,7 @@ u_int32_t max_key_size_from_desc(
has_charset = desc_pos[0];
desc_pos++;
u_int32_t charset_num;
uint32_t charset_num;
if (has_charset == COL_HAS_CHARSET) {
// skip over charsent num
desc_pos += sizeof(charset_num);
......@@ -2521,18 +2521,18 @@ u_int32_t max_key_size_from_desc(
return max_size;
}
u_int32_t pack_key_from_desc(
uint32_t pack_key_from_desc(
uchar* buf,
void* row_desc,
u_int32_t row_desc_size,
uint32_t row_desc_size,
const DBT* pk_key,
const DBT* pk_val
)
{
MULTI_COL_PACK_INFO mcp_info;
u_int32_t num_null_bytes;
u_int32_t num_blobs;
u_int32_t num_pk_columns;
uint32_t num_null_bytes;
uint32_t num_blobs;
uint32_t num_pk_columns;
uchar* blob_lengths = NULL;
uchar* pk_info = NULL;
uchar* pk_data_ptr = NULL;
......@@ -2540,7 +2540,7 @@ u_int32_t pack_key_from_desc(
uchar* fixed_field_ptr = NULL;
uchar* var_field_offset_ptr = NULL;
const uchar* var_field_data_ptr = NULL;
u_int32_t num_offset_bytes;
uint32_t num_offset_bytes;
uchar* packed_key_pos = buf;
uchar* desc_pos = (uchar *)row_desc;
......@@ -2594,11 +2594,11 @@ u_int32_t pack_key_from_desc(
fixed_field_ptr = null_bytes_ptr + num_null_bytes;
var_field_offset_ptr = fixed_field_ptr + mcp_info.fixed_field_size;
var_field_data_ptr = var_field_offset_ptr + mcp_info.len_of_offsets;
while ( (u_int32_t)(desc_pos - (uchar *)row_desc) < row_desc_size) {
while ( (uint32_t)(desc_pos - (uchar *)row_desc) < row_desc_size) {
uchar col_fix_val;
uchar has_charset;
u_int32_t col_pack_val = 0;
u_int32_t key_length = 0;
uint32_t col_pack_val = 0;
uint32_t key_length = 0;
uchar null_bit = desc_pos[0];
desc_pos++;
......@@ -2607,7 +2607,7 @@ u_int32_t pack_key_from_desc(
//
// column is NULLable, need to check the null bytes to see if it is NULL
//
u_int32_t null_offset = 0;
uint32_t null_offset = 0;
bool is_field_null;
memcpy(&null_offset, desc_pos, sizeof(null_offset));
desc_pos += sizeof(null_offset);
......@@ -2639,7 +2639,7 @@ u_int32_t pack_key_from_desc(
has_charset = desc_pos[0];
desc_pos++;
u_int32_t charset_num = 0;
uint32_t charset_num = 0;
if (has_charset == COL_HAS_CHARSET) {
memcpy(&charset_num, desc_pos, sizeof(charset_num));
desc_pos += sizeof(charset_num);
......@@ -2656,9 +2656,9 @@ u_int32_t pack_key_from_desc(
packed_key_pos += key_length;
}
else if (col_fix_val == COL_VAR_FIELD && has_charset == COL_HAS_NO_CHARSET) {
u_int32_t data_start_offset = 0;
uint32_t data_start_offset = 0;
u_int32_t data_size = 0;
uint32_t data_size = 0;
get_var_field_info(
&data_size,
&data_start_offset,
......@@ -2680,8 +2680,8 @@ u_int32_t pack_key_from_desc(
}
else {
const uchar* data_start = NULL;
u_int32_t data_start_offset = 0;
u_int32_t data_size = 0;
uint32_t data_start_offset = 0;
uint32_t data_size = 0;
if (col_fix_val == COL_FIX_FIELD) {
data_start_offset = col_pack_val;
......@@ -2699,11 +2699,11 @@ u_int32_t pack_key_from_desc(
data_start = var_field_data_ptr + data_start_offset;
}
else if (col_fix_val == COL_BLOB_FIELD) {
u_int32_t blob_index = col_pack_val;
u_int32_t blob_offset;
uint32_t blob_index = col_pack_val;
uint32_t blob_offset;
const uchar* blob_ptr = NULL;
u_int32_t field_len;
u_int32_t field_len_bytes = blob_lengths[blob_index];
uint32_t field_len;
uint32_t field_len_bytes = blob_lengths[blob_index];
get_blob_field_info(
&blob_offset,
mcp_info.len_of_offsets,
......@@ -2715,7 +2715,7 @@ u_int32_t pack_key_from_desc(
//
// skip over other blobs to get to the one we want to make a key out of
//
for (u_int32_t i = 0; i < blob_index; i++) {
for (uint32_t i = 0; i < blob_index; i++) {
blob_ptr = unpack_toku_field_blob(
NULL,
blob_ptr,
......@@ -2758,17 +2758,17 @@ u_int32_t pack_key_from_desc(
}
else if (col_fix_val == COL_VAR_PK_OFFSET) {
uchar* tmp_pk_data_ptr = pk_data_ptr;
u_int32_t index_in_pk = col_pack_val;
uint32_t index_in_pk = col_pack_val;
//
// skip along in pk to the right column
//
for (u_int32_t i = 0; i < index_in_pk; i++) {
for (uint32_t i = 0; i < index_in_pk; i++) {
if (pk_info[2*i] == COL_FIX_FIELD) {
tmp_pk_data_ptr += pk_info[2*i + 1];
}
else if (pk_info[2*i] == COL_VAR_FIELD) {
u_int32_t len_bytes = pk_info[2*i + 1];
u_int32_t len;
uint32_t len_bytes = pk_info[2*i + 1];
uint32_t len;
if (len_bytes == 1) {
len = tmp_pk_data_ptr[0];
tmp_pk_data_ptr++;
......@@ -2789,15 +2789,15 @@ u_int32_t pack_key_from_desc(
//
// at this point, tmp_pk_data_ptr is pointing at the column
//
u_int32_t is_fix_field = pk_info[2*index_in_pk];
uint32_t is_fix_field = pk_info[2*index_in_pk];
if (is_fix_field == COL_FIX_FIELD) {
memcpy(packed_key_pos, tmp_pk_data_ptr, key_length);
packed_key_pos += key_length;
}
else if (is_fix_field == COL_VAR_FIELD) {
const uchar* data_start = NULL;
u_int32_t data_size = 0;
u_int32_t len_bytes = pk_info[2*index_in_pk + 1];
uint32_t data_size = 0;
uint32_t len_bytes = pk_info[2*index_in_pk + 1];
if (len_bytes == 1) {
data_size = tmp_pk_data_ptr[0];
tmp_pk_data_ptr++;
......@@ -2842,7 +2842,7 @@ u_int32_t pack_key_from_desc(
}
}
assert( (u_int32_t)(desc_pos - (uchar *)row_desc) == row_desc_size);
assert( (uint32_t)(desc_pos - (uchar *)row_desc) == row_desc_size);
//
// now append the primary key to the end of the key
......@@ -2856,7 +2856,7 @@ u_int32_t pack_key_from_desc(
packed_key_pos += (pk_key->size - 1);
}
return (u_int32_t)(packed_key_pos - buf); //
return (uint32_t)(packed_key_pos - buf); //
}
bool fields_have_same_name(
......
......@@ -47,7 +47,7 @@
// used for queries
typedef struct st_col_pack_info {
u_int32_t col_pack_val; //offset if fixed, pack_index if var
uint32_t col_pack_val; //offset if fixed, pack_index if var
} COL_PACK_INFO;
//
......@@ -62,8 +62,8 @@ typedef struct st_col_pack_info {
// To figure out where the blobs start, find the last offset listed (if offsets exist)
//
typedef struct st_multi_col_pack_info {
u_int32_t fixed_field_size; //where the fixed length stuff ends and the offsets for var stuff begins
u_int32_t len_of_offsets; //length of the offset bytes in a packed row
uint32_t fixed_field_size; //where the fixed length stuff ends and the offsets for var stuff begins
uint32_t len_of_offsets; //length of the offset bytes in a packed row
} MULTI_COL_PACK_INFO;
......@@ -91,10 +91,10 @@ typedef struct st_key_and_col_info {
// length_bytes[i] is 0
// 'i' shows up in blob_fields
//
u_int16_t* field_lengths; //stores the field lengths of fixed size fields (1<<16 - 1 max),
uint16_t* field_lengths; //stores the field lengths of fixed size fields (1<<16 - 1 max),
uchar* length_bytes; // stores the length of lengths of varchars and varbinaries
u_int32_t* blob_fields; // list of indexes of blob fields,
u_int32_t num_blobs; // number of blobs in the table
uint32_t* blob_fields; // list of indexes of blob fields,
uint32_t num_blobs; // number of blobs in the table
//
// val packing info for all dictionaries. i'th one represents info for i'th dictionary
//
......@@ -105,33 +105,33 @@ typedef struct st_key_and_col_info {
// The number of var fields in a val for dictionary i can be evaluated by
// mcp_info[i].len_of_offsets/num_offset_bytes.
//
u_int32_t num_offset_bytes; //number of bytes needed to encode the offset
uint32_t num_offset_bytes; //number of bytes needed to encode the offset
} KEY_AND_COL_INFO;
void get_var_field_info(
u_int32_t* field_len,
u_int32_t* start_offset,
u_int32_t var_field_index,
uint32_t* field_len,
uint32_t* start_offset,
uint32_t var_field_index,
const uchar* var_field_offset_ptr,
u_int32_t num_offset_bytes
uint32_t num_offset_bytes
);
void get_blob_field_info(
u_int32_t* start_offset,
u_int32_t len_of_offsets,
uint32_t* start_offset,
uint32_t len_of_offsets,
const uchar* var_field_data_ptr,
u_int32_t num_offset_bytes
uint32_t num_offset_bytes
);
static inline u_int32_t get_blob_field_len(
static inline uint32_t get_blob_field_len(
const uchar* from_tokudb,
u_int32_t len_bytes
uint32_t len_bytes
)
{
u_int32_t length = 0;
uint32_t length = 0;
switch (len_bytes) {
case (1):
length = (u_int32_t)(*from_tokudb);
length = (uint32_t)(*from_tokudb);
break;
case (2):
length = uint2korr(from_tokudb);
......@@ -152,11 +152,11 @@ static inline u_int32_t get_blob_field_len(
static inline const uchar* unpack_toku_field_blob(
uchar *to_mysql,
const uchar* from_tokudb,
u_int32_t len_bytes,
uint32_t len_bytes,
bool skip
)
{
u_int32_t length = 0;
uint32_t length = 0;
const uchar* data_ptr = NULL;
if (!skip) {
memcpy(to_mysql, from_tokudb, len_bytes);
......@@ -194,16 +194,16 @@ TOKU_TYPE mysql_to_toku_type (Field* field);
uchar* pack_toku_varbinary_from_desc(
uchar* to_tokudb,
const uchar* from_desc,
u_int32_t key_part_length, //number of bytes to use to encode the length in to_tokudb
u_int32_t field_length //length of field
uint32_t key_part_length, //number of bytes to use to encode the length in to_tokudb
uint32_t field_length //length of field
);
uchar* pack_toku_varstring_from_desc(
uchar* to_tokudb,
const uchar* from_desc,
u_int32_t key_part_length, //number of bytes to use to encode the length in to_tokudb
u_int32_t field_length,
u_int32_t charset_num//length of field
uint32_t key_part_length, //number of bytes to use to encode the length in to_tokudb
uint32_t field_length,
uint32_t charset_num//length of field
);
......@@ -211,21 +211,21 @@ uchar* pack_toku_key_field(
uchar* to_tokudb,
uchar* from_mysql,
Field* field,
u_int32_t key_part_length //I really hope this is temporary as I phase out the pack_cmp stuff
uint32_t key_part_length //I really hope this is temporary as I phase out the pack_cmp stuff
);
uchar* pack_key_toku_key_field(
uchar* to_tokudb,
uchar* from_mysql,
Field* field,
u_int32_t key_part_length //I really hope this is temporary as I phase out the pack_cmp stuff
uint32_t key_part_length //I really hope this is temporary as I phase out the pack_cmp stuff
);
uchar* unpack_toku_key_field(
uchar* to_mysql,
uchar* from_tokudb,
Field* field,
u_int32_t key_part_length
uint32_t key_part_length
);
......@@ -263,11 +263,11 @@ static inline ulonglong hpk_char_to_num(uchar* val) {
int tokudb_compare_two_keys(
const void* new_key_data,
const u_int32_t new_key_size,
const uint32_t new_key_size,
const void* saved_key_data,
const u_int32_t saved_key_size,
const uint32_t saved_key_size,
const void* row_desc,
const u_int32_t row_desc_size,
const uint32_t row_desc_size,
bool cmp_prefix
);
......@@ -286,43 +286,43 @@ int create_toku_key_descriptor(
);
u_int32_t create_toku_main_key_pack_descriptor (
uint32_t create_toku_main_key_pack_descriptor (
uchar* buf
);
u_int32_t get_max_clustering_val_pack_desc_size(
uint32_t get_max_clustering_val_pack_desc_size(
TABLE_SHARE* table_share
);
u_int32_t create_toku_clustering_val_pack_descriptor (
uint32_t create_toku_clustering_val_pack_descriptor (
uchar* buf,
uint pk_index,
TABLE_SHARE* table_share,
KEY_AND_COL_INFO* kc_info,
u_int32_t keynr,
uint32_t keynr,
bool is_clustering
);
static inline bool is_key_clustering(
void* row_desc,
u_int32_t row_desc_size
uint32_t row_desc_size
)
{
return (row_desc_size > 0);
}
u_int32_t pack_clustering_val_from_desc(
uint32_t pack_clustering_val_from_desc(
uchar* buf,
void* row_desc,
u_int32_t row_desc_size,
uint32_t row_desc_size,
const DBT* pk_val
);
u_int32_t get_max_secondary_key_pack_desc_size(
uint32_t get_max_secondary_key_pack_desc_size(
KEY_AND_COL_INFO* kc_info
);
u_int32_t create_toku_secondary_key_pack_descriptor (
uint32_t create_toku_secondary_key_pack_descriptor (
uchar* buf,
bool has_hpk,
uint pk_index,
......@@ -335,23 +335,23 @@ u_int32_t create_toku_secondary_key_pack_descriptor (
static inline bool is_key_pk(
void* row_desc,
u_int32_t row_desc_size
uint32_t row_desc_size
)
{
uchar* buf = (uchar *)row_desc;
return buf[0];
}
u_int32_t max_key_size_from_desc(
uint32_t max_key_size_from_desc(
void* row_desc,
u_int32_t row_desc_size
uint32_t row_desc_size
);
u_int32_t pack_key_from_desc(
uint32_t pack_key_from_desc(
uchar* buf,
void* row_desc,
u_int32_t row_desc_size,
uint32_t row_desc_size,
const DBT* pk_key,
const DBT* pk_val
);
......
......@@ -209,7 +209,7 @@ static inline void make_name(char *newname, const char *tablename, const char *d
nn += sprintf(nn, "-%s", dictname);
}
static inline void commit_txn(DB_TXN* txn, u_int32_t flags) {
static inline void commit_txn(DB_TXN* txn, uint32_t flags) {
int r;
r = txn->commit(txn, flags);
if (r != 0) {
......
......@@ -46,7 +46,7 @@ static MYSQL_THDVAR_BOOL(commit_sync,
"sync on txn commit",
/* check */ NULL,
/* update */ NULL,
/* default*/ TRUE
/* default*/ true
);
static MYSQL_THDVAR_UINT(pk_insert_mode,
......@@ -64,49 +64,49 @@ static MYSQL_THDVAR_BOOL(load_save_space,
"if on, intial loads are slower but take less space",
NULL,
NULL,
FALSE
false
);
static MYSQL_THDVAR_BOOL(disable_slow_alter,
0,
"if on, alter tables that require copy are disabled",
NULL,
NULL,
FALSE
false
);
static MYSQL_THDVAR_BOOL(disable_hot_alter,
0,
"if on, hot alter table is disabled",
NULL,
NULL,
FALSE
false
);
static MYSQL_THDVAR_BOOL(create_index_online,
0,
"if on, create index done online",
NULL,
NULL,
TRUE
true
);
static MYSQL_THDVAR_BOOL(disable_prefetching,
0,
"if on, prefetching disabled",
NULL,
NULL,
FALSE
false
);
static MYSQL_THDVAR_BOOL(prelock_empty,
0,
"Tokudb Prelock Empty Table",
NULL,
NULL,
TRUE
true
);
static MYSQL_THDVAR_BOOL(log_client_errors,
0,
"Tokudb Log Client Errors",
NULL,
NULL,
FALSE
false
);
static MYSQL_THDVAR_UINT(block_size,
0,
......@@ -150,7 +150,7 @@ tokudb_checkpoint_lock_update(
const void* save)
{
my_bool* val = (my_bool *) var_ptr;
*val= *(my_bool *) save ? TRUE : FALSE;
*val= *(my_bool *) save ? true : false;
if (*val) {
tokudb_checkpoint_lock(thd);
}
......@@ -164,7 +164,7 @@ static MYSQL_THDVAR_BOOL(checkpoint_lock,
"Tokudb Checkpoint Lock",
NULL,
tokudb_checkpoint_lock_update,
FALSE
false
);
static const char *tokudb_row_format_names[] = {
......@@ -255,16 +255,16 @@ void toku_hton_assert_fail(const char* expr_as_string, const char * fun, const c
//my_bool tokudb_shared_data = FALSE;
static u_int32_t tokudb_init_flags =
//my_bool tokudb_shared_data = false;
static uint32_t tokudb_init_flags =
DB_CREATE | DB_THREAD | DB_PRIVATE |
DB_INIT_LOCK |
DB_INIT_MPOOL |
DB_INIT_TXN |
DB_INIT_LOG |
DB_RECOVER;
static u_int32_t tokudb_env_flags = 0;
// static u_int32_t tokudb_lock_type = DB_LOCK_DEFAULT;
static uint32_t tokudb_env_flags = 0;
// static uint32_t tokudb_lock_type = DB_LOCK_DEFAULT;
// static ulong tokudb_log_buffer_size = 0;
// static ulong tokudb_log_file_size = 0;
static ulonglong tokudb_cache_size = 0;
......@@ -276,9 +276,9 @@ static char *tokudb_log_dir;
// static ulong tokudb_region_size = 0;
// static ulong tokudb_cache_parts = 1;
const char *tokudb_hton_name = "TokuDB";
static u_int32_t tokudb_checkpointing_period;
u_int32_t tokudb_write_status_frequency;
u_int32_t tokudb_read_status_frequency;
static uint32_t tokudb_checkpointing_period;
uint32_t tokudb_write_status_frequency;
uint32_t tokudb_read_status_frequency;
#ifdef TOKUDB_VERSION
char *tokudb_version = (char*) TOKUDB_VERSION;
#else
......@@ -444,7 +444,7 @@ static int tokudb_init_func(void *p) {
}
if (tokudb_cache_size) {
DBUG_PRINT("info", ("tokudb_cache_size: %lld\n", tokudb_cache_size));
r = db_env->set_cachesize(db_env, (u_int32_t)(tokudb_cache_size >> 30), (u_int32_t)(tokudb_cache_size % (1024L * 1024L * 1024L)), 1);
r = db_env->set_cachesize(db_env, (uint32_t)(tokudb_cache_size >> 30), (uint32_t)(tokudb_cache_size % (1024L * 1024L * 1024L)), 1);
if (r) {
DBUG_PRINT("info", ("set_cachesize %d\n", r));
goto error;
......@@ -462,7 +462,7 @@ static int tokudb_init_func(void *p) {
}
}
u_int32_t gbytes, bytes; int parts;
uint32_t gbytes, bytes; int parts;
r = db_env->get_cachesize(db_env, &gbytes, &bytes, &parts);
if (r == 0)
if (tokudb_debug & TOKUDB_DEBUG_INIT)
......@@ -551,7 +551,7 @@ static int tokudb_init_func(void *p) {
//3938: succeeded, set the init status flag and unlock
tokudb_hton_initialized = 1;
rw_unlock(&tokudb_hton_initialized_lock);
DBUG_RETURN(FALSE);
DBUG_RETURN(false);
error:
if (metadata_db) {
......@@ -567,7 +567,7 @@ static int tokudb_init_func(void *p) {
// 3938: failed to initialized, drop the flag and lock
tokudb_hton_initialized = 0;
rw_unlock(&tokudb_hton_initialized_lock);
DBUG_RETURN(TRUE);
DBUG_RETURN(true);
}
static int tokudb_done_func(void *p) {
......@@ -637,7 +637,7 @@ bool tokudb_flush_logs(handlerton * hton) {
TOKUDB_DBUG_ENTER("tokudb_flush_logs");
int error;
bool result = 0;
u_int32_t curr_tokudb_checkpointing_period = 0;
uint32_t curr_tokudb_checkpointing_period = 0;
//
// get the current checkpointing period
......@@ -780,7 +780,7 @@ void txn_progress_func(TOKU_TXN_PROGRESS progress, void* extra) {
}
static void commit_txn_with_progress(DB_TXN* txn, u_int32_t flags, THD* thd) {
static void commit_txn_with_progress(DB_TXN* txn, uint32_t flags, THD* thd) {
int r;
struct txn_progress_info info;
info.thd = thd;
......@@ -805,7 +805,7 @@ static void abort_txn_with_progress(DB_TXN* txn, THD* thd) {
static int tokudb_commit(handlerton * hton, THD * thd, bool all) {
TOKUDB_DBUG_ENTER("tokudb_commit");
DBUG_PRINT("trans", ("ending transaction %s", all ? "all" : "stmt"));
u_int32_t syncflag = THDVAR(thd, commit_sync) ? 0 : DB_TXN_NOSYNC;
uint32_t syncflag = THDVAR(thd, commit_sync) ? 0 : DB_TXN_NOSYNC;
tokudb_trx_data *trx = (tokudb_trx_data *) thd_data_get(thd, hton->slot);
DB_TXN **txn = all ? &trx->all : &trx->stmt;
if (*txn) {
......@@ -1059,7 +1059,7 @@ static int tokudb_discover(handlerton *hton, THD* thd, const char *db,
TOKUDB_DBUG_RETURN(error);
}
static int store_dbname_tablename_size(TABLE *table, char *name, u_int64_t size, THD *thd) {
static int store_dbname_tablename_size(TABLE *table, char *name, uint64_t size, THD *thd) {
char *tp = strrchr(name, '/');
assert(tp);
char *tablename = tp + 1;
......@@ -1181,7 +1181,7 @@ static int tokudb_get_user_data_size(TABLE *table, THD *thd, bool exact) {
if (!error) {
char* name = (char *)curr_key.data;
char* newname;
u_int64_t curr_num_bytes = 0;
uint64_t curr_num_bytes = 0;
DB_BTREE_STAT64 dict_stats;
error = db_create(&curr_db, db_env, 0);
......@@ -1241,14 +1241,14 @@ static int tokudb_get_user_data_size(TABLE *table, THD *thd, bool exact) {
// in this case, we have a hidden primary key, do not
// want to report space taken up by the hidden primary key to the user
//
u_int64_t hpk_space = TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH*dict_stats.bt_ndata;
uint64_t hpk_space = TOKUDB_HIDDEN_PRIMARY_KEY_LENGTH*dict_stats.bt_ndata;
curr_num_bytes = (hpk_space > curr_num_bytes) ? 0 : curr_num_bytes - hpk_space;
}
else {
//
// one infinity byte per key needs to be subtracted
//
u_int64_t inf_byte_space = dict_stats.bt_ndata;
uint64_t inf_byte_space = dict_stats.bt_ndata;
curr_num_bytes = (inf_byte_space > curr_num_bytes) ? 0 : curr_num_bytes - inf_byte_space;
}
......@@ -1456,7 +1456,7 @@ static bool tokudb_show_status(handlerton * hton, THD * thd, stat_print_fn * sta
default:
break;
}
return FALSE;
return false;
}
static void tokudb_print_error(const DB_ENV * db_env, const char *db_errpfx, const char *buffer) {
......
......@@ -37,7 +37,7 @@ srv_row_format_t get_row_format(THD *thd);
extern HASH tokudb_open_tables;
extern pthread_mutex_t tokudb_mutex;
extern pthread_mutex_t tokudb_meta_mutex;
extern u_int32_t tokudb_write_status_frequency;
extern u_int32_t tokudb_read_status_frequency;
extern uint32_t tokudb_write_status_frequency;
extern uint32_t tokudb_read_status_frequency;
#endif //#ifdef _HATOKU_HTON
Markdown is supported
0%
or
You are about to add 0 people to the discussion. Proceed with caution.
Finish editing this message first!
Please register or to comment