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mariadb/storage/tokudb/ha_tokudb_alter_56.cc
Rich Prohaska 1eb1e55daa #5023 always compile in the update callback in the handlerton (for mysql 5.6) refs[t:5023] 
git-svn-id: file:///svn/mysql/tokudb-engine/tokudb-engine@44266 c7de825b-a66e-492c-adef-691d508d4ae1
2013-04-17 00:02:11 -04:00

1144 lines
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#if 50600 <= MYSQL_VERSION_ID && MYSQL_VERSION_ID <= 50699
static bool
tables_have_same_keys(TABLE* table, TABLE* altered_table, bool print_error, bool check_field_index) {
bool retval;
if (table->s->keys != altered_table->s->keys) {
if (print_error) {
sql_print_error("tables have different number of keys");
}
retval = false;
goto cleanup;
}
if (table->s->primary_key != altered_table->s->primary_key) {
if (print_error) {
sql_print_error(
"Tables have different primary keys, %d %d",
table->s->primary_key,
altered_table->s->primary_key
);
}
retval = false;
goto cleanup;
}
for (u_int32_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)) {
if (print_error) {
sql_print_error(
"key %d has different name, %s %s",
i,
curr_orig_key->name,
curr_altered_key->name
);
}
retval = false;
goto cleanup;
}
if (((curr_orig_key->flags & HA_CLUSTERING) == 0) != ((curr_altered_key->flags & HA_CLUSTERING) == 0)) {
if (print_error) {
sql_print_error(
"keys disagree on if they are clustering, %d, %d",
curr_orig_key->key_parts,
curr_altered_key->key_parts
);
}
retval = false;
goto cleanup;
}
if (((curr_orig_key->flags & HA_NOSAME) == 0) != ((curr_altered_key->flags & HA_NOSAME) == 0)) {
if (print_error) {
sql_print_error(
"keys disagree on if they are unique, %d, %d",
curr_orig_key->key_parts,
curr_altered_key->key_parts
);
}
retval = false;
goto cleanup;
}
if (curr_orig_key->key_parts != curr_altered_key->key_parts) {
if (print_error) {
sql_print_error(
"keys have different number of parts, %d, %d",
curr_orig_key->key_parts,
curr_altered_key->key_parts
);
}
retval = false;
goto cleanup;
}
//
// now verify that each field in the key is the same
//
for (u_int32_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;
Field* curr_altered_field = curr_altered_part->field;
if (curr_orig_part->length != curr_altered_part->length) {
if (print_error) {
sql_print_error(
"Key %s has different length at index %d",
curr_orig_key->name,
j
);
}
retval = false;
goto cleanup;
}
bool are_fields_same;
are_fields_same = (check_field_index) ?
(curr_orig_part->fieldnr == curr_altered_part->fieldnr &&
fields_are_same_type(curr_orig_field, curr_altered_field)) :
(are_two_fields_same(curr_orig_field,curr_altered_field));
if (!are_fields_same) {
if (print_error) {
sql_print_error(
"Key %s has different field at index %d",
curr_orig_key->name,
j
);
}
retval = false;
goto cleanup;
}
}
}
retval = true;
cleanup:
return retval;
}
//
// MySQL sets the null_bit as a number that you can bit-wise AND a byte to
// 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;
switch(null_bit) {
case (1):
retval = 0;
break;
case (2):
retval = 1;
break;
case (4):
retval = 2;
break;
case (8):
retval = 3;
break;
case (16):
retval = 4;
break;
case (32):
retval = 5;
break;
case (64):
retval = 6;
break;
case (128):
retval = 7;
break;
default:
assert(false);
}
return retval;
}
//
// returns the index of the null bit of field.
//
static inline u_int32_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;
return offset*8 + get_null_bit_position(null_bit);
}
#if 0
static bool
are_null_bits_in_order(TABLE* table) {
u_int32_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(
table,
curr_field
);
if (!first && pos != curr_null_pos+1){
retval = false;
break;
}
first = false;
curr_null_pos = pos;
}
}
return retval;
}
#endif
static u_int32_t
get_first_null_bit_pos(TABLE* table) {
u_int32_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);
if (nullable) {
table_pos = get_overall_null_bit_position(
table,
curr_field
);
break;
}
}
return table_pos;
}
#if 0
static bool
is_column_default_null(TABLE* src_table, u_int32_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);
is_null_default = is_overall_null_position_set(
src_table->s->default_values,
null_bit_position
);
}
return is_null_default;
}
#endif
#define UP_COL_ADD_OR_DROP 0
#define COL_DROP 0xaa
#define COL_ADD 0xbb
#define COL_FIXED 0xcc
#define COL_VAR 0xdd
#define COL_BLOB 0xee
#define STATIC_ROW_MUTATOR_SIZE 1+8+2+8+8+8
/*
how much space do I need for the mutators?
static stuff first:
1 - UP_COL_ADD_OR_DROP
8 - old null, new null
2 - old num_offset, new num_offset
8 - old fixed_field size, new fixed_field_size
8 - old and new length of offsets
8 - old and new starting null bit position
TOTAL: 27
dynamic stuff:
4 - number of columns
for each column:
1 - add or drop
1 - is nullable
4 - if nullable, position
1 - if add, whether default is null or not
1 - if fixed, var, or not
for fixed, entire default
for var, 4 bytes length, then entire default
for blob, nothing
So, an upperbound is 4 + num_fields(12) + all default stuff
static blob stuff:
4 - num blobs
1 byte for each num blobs in old table
So, an upperbound is 4 + kc_info->num_blobs
dynamic blob stuff:
for each blob added:
1 - state if we are adding or dropping
4 - blob index
if add, 1 len bytes
at most, 4 0's
So, upperbound is num_blobs(1+4+1+4) = num_columns*10
*/
static u_int32_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
)
{
//
// start packing extra
//
uchar* pos = buf;
// says what the operation is
pos[0] = UP_COL_ADD_OR_DROP;
pos++;
//
// null byte information
//
memcpy(pos, &orig_table->s->null_bytes, sizeof(orig_table->s->null_bytes));
pos += sizeof(orig_table->s->null_bytes);
memcpy(pos, &altered_table->s->null_bytes, sizeof(orig_table->s->null_bytes));
pos += sizeof(altered_table->s->null_bytes);
//
// num_offset_bytes
//
assert(orig_kc_info->num_offset_bytes <= 2);
pos[0] = orig_kc_info->num_offset_bytes;
pos++;
assert(altered_kc_info->num_offset_bytes <= 2);
pos[0] = altered_kc_info->num_offset_bytes;
pos++;
//
// size of fixed fields
//
u_int32_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;
memcpy(pos, &fixed_field_size, sizeof(fixed_field_size));
pos += sizeof(fixed_field_size);
//
// length of offsets
//
u_int32_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);
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);
memcpy(pos, &altered_start_null_pos, sizeof(altered_start_null_pos));
pos += sizeof(altered_start_null_pos);
assert((pos-buf) == STATIC_ROW_MUTATOR_SIZE);
return pos - buf;
}
static u_int32_t
fill_dynamic_row_mutator(
uchar* buf,
u_int32_t* columns,
u_int32_t num_columns,
TABLE* src_table,
KEY_AND_COL_INFO* src_kc_info,
u_int32_t keynr,
bool is_add,
bool* out_has_blobs
)
{
uchar* pos = buf;
bool has_blobs = false;
u_int32_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];
Field* curr_field = src_table->field[curr_index];
pos[0] = is_add ? COL_ADD : COL_DROP;
pos++;
//
// NULL bit information
//
bool is_null_default = false;
bool nullable = curr_field->null_bit != 0;
if (!nullable) {
pos[0] = 0;
pos++;
}
else {
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);
memcpy(pos, &null_bit_position, sizeof(null_bit_position));
pos += sizeof(null_bit_position);
//
// if adding a column, write the value of the default null_bit
//
if (is_add) {
is_null_default = is_overall_null_position_set(
src_table->s->default_values,
null_bit_position
);
pos[0] = is_null_default ? 1 : 0;
pos++;
}
}
if (src_kc_info->field_lengths[curr_index] != 0) {
// we have a fixed field being dropped
// store the offset and the number of bytes
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;
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];
memcpy(pos, &num_bytes, sizeof(num_bytes));
pos += sizeof(num_bytes);
if (is_add && !is_null_default) {
uint curr_field_offset = field_offset(curr_field, src_table);
memcpy(
pos,
src_table->s->default_values + curr_field_offset,
num_bytes
);
pos += num_bytes;
}
}
else if (src_kc_info->length_bytes[curr_index] != 0) {
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;
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(
src_table->s->default_values + curr_field_offset,
len_bytes
);
memcpy(pos, &data_length, sizeof(data_length));
pos += sizeof(data_length);
memcpy(
pos,
src_table->s->default_values + curr_field_offset + len_bytes,
data_length
);
pos += data_length;
}
}
else {
pos[0] = COL_BLOB;
pos++;
has_blobs = true;
}
}
*out_has_blobs = has_blobs;
return pos-buf;
}
static u_int32_t
fill_static_blob_row_mutator(
uchar* buf,
TABLE* src_table,
KEY_AND_COL_INFO* src_kc_info
)
{
uchar* pos = buf;
// copy number of blobs
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];
Field* field = src_table->field[curr_field_index];
u_int32_t len_bytes = field->row_pack_length();
assert(len_bytes <= 4);
pos[0] = len_bytes;
pos++;
}
return pos-buf;
}
static u_int32_t
fill_dynamic_blob_row_mutator(
uchar* buf,
u_int32_t* columns,
u_int32_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];
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++) {
if (curr_field_index == src_kc_info->blob_fields[j]) {
blob_index = j;
break;
}
}
// assert we found blob in list
assert(blob_index < src_kc_info->num_blobs);
pos[0] = is_add ? COL_ADD : COL_DROP;
pos++;
memcpy(pos, &blob_index, sizeof(blob_index));
pos += sizeof(blob_index);
if (is_add) {
u_int32_t len_bytes = curr_field->row_pack_length();
assert(len_bytes <= 4);
pos[0] = len_bytes;
pos++;
// create a zero length blob field that can be directly copied in
// for now, in MySQL, we can only have blob fields
// that have no default value
memset(pos, 0, len_bytes);
pos += len_bytes;
}
}
else {
// not a blob, continue
continue;
}
}
return pos-buf;
}
// 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
ha_tokudb::fill_row_mutator(
uchar* buf,
u_int32_t* columns,
u_int32_t num_columns,
TABLE* altered_table,
KEY_AND_COL_INFO* altered_kc_info,
u_int32_t keynr,
bool is_add
)
{
if (tokudb_debug & TOKUDB_DEBUG_ALTER_TABLE_INFO) {
printf("*****some info:*************\n");
printf(
"old things: num_null_bytes %d, num_offset_bytes %d, fixed_field_size %d, fixed_field_size %d\n",
table->s->null_bytes,
share->kc_info.num_offset_bytes,
share->kc_info.mcp_info[keynr].fixed_field_size,
share->kc_info.mcp_info[keynr].len_of_offsets
);
printf(
"new things: num_null_bytes %d, num_offset_bytes %d, fixed_field_size %d, fixed_field_size %d\n",
altered_table->s->null_bytes,
altered_kc_info->num_offset_bytes,
altered_kc_info->mcp_info[keynr].fixed_field_size,
altered_kc_info->mcp_info[keynr].len_of_offsets
);
printf("****************************\n");
}
uchar* pos = buf;
bool has_blobs = false;
pos += fill_static_row_mutator(
pos,
table,
altered_table,
&share->kc_info,
altered_kc_info,
keynr
);
if (is_add) {
pos += fill_dynamic_row_mutator(
pos,
columns,
num_columns,
altered_table,
altered_kc_info,
keynr,
is_add,
&has_blobs
);
}
else {
pos += fill_dynamic_row_mutator(
pos,
columns,
num_columns,
table,
&share->kc_info,
keynr,
is_add,
&has_blobs
);
}
if (has_blobs) {
pos += fill_static_blob_row_mutator(
pos,
table,
&share->kc_info
);
if (is_add) {
pos += fill_dynamic_blob_row_mutator(
pos,
columns,
num_columns,
altered_table,
altered_kc_info,
is_add
);
}
else {
pos += fill_dynamic_blob_row_mutator(
pos,
columns,
num_columns,
table,
&share->kc_info,
is_add
);
}
}
return pos-buf;
}
static bool
column_rename_supported(
Alter_inplace_info *ha_alter_info,
TABLE* orig_table,
TABLE* new_table
)
{
bool retval = false;
bool keys_same_for_cr;
uint num_fields_with_different_names = 0;
uint field_with_different_name = orig_table->s->fields;
if (orig_table->s->fields != new_table->s->fields) {
retval = false;
goto cleanup;
}
if (ha_alter_info->handler_flags & Alter_inplace_info::ALTER_COLUMN_ORDER) {
retval = false;
goto cleanup;
}
for (uint i = 0; i < orig_table->s->fields; i++) {
Field* orig_field = orig_table->field[i];
Field* new_field = new_table->field[i];
if (!fields_are_same_type(orig_field, new_field)) {
retval = false;
goto cleanup;
}
if (!fields_have_same_name(orig_field, new_field)) {
num_fields_with_different_names++;
field_with_different_name = i;
}
}
// only allow one renamed field
if (num_fields_with_different_names != 1) {
retval = false;
goto cleanup;
}
assert(field_with_different_name < orig_table->s->fields);
//
// at this point, we have verified that the two tables have
// the same field types and with ONLY one field with a different name.
// We have also identified the field with the different name
//
// Now we need to check the indexes
//
keys_same_for_cr = tables_have_same_keys(
orig_table,
new_table,
false,
true
);
if (!keys_same_for_cr) {
retval = false;
goto cleanup;
}
retval = true;
cleanup:
return retval;
}
static int
find_changed_columns(
u_int32_t* changed_columns,
u_int32_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;
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) {
sql_print_error("error in determining changed columns");
retval = 1;
goto cleanup;
}
Field* curr_field_in_new = bigger_table->field[curr_new_col_index];
Field* curr_field_in_orig = smaller_table->field[i];
while (!fields_have_same_name(curr_field_in_orig, curr_field_in_new)) {
changed_columns[curr_num_changed_columns] = curr_new_col_index;
curr_num_changed_columns++;
curr_new_col_index++;
curr_field_in_new = bigger_table->field[curr_new_col_index];
if (curr_new_col_index >= bigger_table->s->fields) {
sql_print_error("error in determining changed columns");
retval = 1;
goto cleanup;
}
}
// at this point, curr_field_in_orig and curr_field_in_new should be the same, let's verify
// make sure the two fields that have the same name are ok
if (!are_two_fields_same(curr_field_in_orig, curr_field_in_new)) {
sql_print_error(
"Two fields that were supposedly the same are not: \
%s in original, %s in new",
curr_field_in_orig->field_name,
curr_field_in_new->field_name
);
retval = 1;
goto cleanup;
}
}
for (uint i = curr_new_col_index; i < bigger_table->s->fields; i++) {
changed_columns[curr_num_changed_columns] = i;
curr_num_changed_columns++;
}
*num_changed_columns = curr_num_changed_columns;
retval = 0;
cleanup:
return retval;
}
class ha_tokudb_add_index_ctx : public inplace_alter_handler_ctx {
public:
ha_tokudb_add_index_ctx(bool _incremented_num_DBs, bool _modified_DBs) : incremented_num_DBs(_incremented_num_DBs), modified_DBs(_modified_DBs) {
}
virtual ~ha_tokudb_add_index_ctx() {
}
public:
bool incremented_num_DBs, modified_DBs;
};
enum_alter_inplace_result
ha_tokudb::check_if_supported_inplace_alter(TABLE *altered_table, Alter_inplace_info *ha_alter_info) {
TOKUDB_DBUG_ENTER("check_if_supported_alter");
if (tokudb_debug & TOKUDB_DEBUG_ALTER_TABLE_INFO) {
print_alter_info(altered_table, ha_alter_info);
}
THD *thd = ha_thd();
enum_alter_inplace_result result = HA_ALTER_INPLACE_NOT_SUPPORTED; // default is NOT inplace
// column rename
if ((ha_alter_info->handler_flags & ~(Alter_inplace_info::ALTER_COLUMN_NAME + Alter_inplace_info::ALTER_COLUMN_DEFAULT)) == 0) {
// we have identified a possible column rename,
// but let's do some more checks
// we will only allow an hcr if there are no changes
// in column positions
#if 0 // TODO
if (alter_info->contains_first_or_after) {
result = HA_ALTER_INPLACE_NOT_SUPPORTED;
} else
#endif
{
// now need to verify that one and only one column
// has changed only its name. If we find anything to
// the contrary, we don't allow it, also check indexes
bool cr_supported = column_rename_supported(ha_alter_info, table, altered_table);
if (cr_supported)
result = HA_ALTER_INPLACE_NO_LOCK;
}
} else
// add index
if (ha_alter_info->handler_flags == Alter_inplace_info::ADD_INDEX ||
ha_alter_info->handler_flags == Alter_inplace_info::ADD_UNIQUE_INDEX) { // && tables_have_same_keys TODO???
assert(ha_alter_info->index_drop_count == 0);
result = HA_ALTER_INPLACE_SHARED_LOCK;
// TODO allow multiple hot indexes via alter table add key. don't forget to change the store_lock function.x
if (get_create_index_online(thd) && ha_alter_info->index_add_count == 1 && thd_sql_command(thd) == SQLCOM_CREATE_INDEX)
result = HA_ALTER_INPLACE_NO_LOCK_AFTER_PREPARE;
} else
// drop index
if (ha_alter_info->handler_flags == Alter_inplace_info::DROP_INDEX ||
ha_alter_info->handler_flags == Alter_inplace_info::DROP_UNIQUE_INDEX) { // && tables_have_same_keys TODO???
assert(ha_alter_info->index_add_count == 0);
result = HA_ALTER_INPLACE_EXCLUSIVE_LOCK;;
} else
// add column
if (ha_alter_info->handler_flags == Alter_inplace_info::ADD_COLUMN ||
ha_alter_info->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;
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];
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);
}
}
result = HA_ALTER_INPLACE_EXCLUSIVE_LOCK;
}
} else
// drop column
if (ha_alter_info->handler_flags == Alter_inplace_info::DROP_COLUMN ||
ha_alter_info->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;
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];
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);
}
}
result = HA_ALTER_INPLACE_EXCLUSIVE_LOCK;
}
}
if (result == HA_ALTER_INPLACE_NOT_SUPPORTED && get_disable_slow_alter(thd)) {
print_error(HA_ERR_UNSUPPORTED, MYF(0));
result = HA_ALTER_ERROR;
}
DBUG_RETURN(result);
}
bool
ha_tokudb::prepare_inplace_alter_table(TABLE *altered_table, Alter_inplace_info *ha_alter_info) {
TOKUDB_DBUG_ENTER("prepare_inplace_alter_table");
bool result = false; // success
DBUG_RETURN(result);
}
bool
ha_tokudb::inplace_alter_table(TABLE *altered_table, Alter_inplace_info *ha_alter_info) {
TOKUDB_DBUG_ENTER("inplace_alter_table");
int error = 0;
if (ha_alter_info->handler_flags == Alter_inplace_info::ADD_INDEX ||
ha_alter_info->handler_flags == Alter_inplace_info::ADD_UNIQUE_INDEX) {
error = alter_table_add_index(altered_table, ha_alter_info);
} else
if (ha_alter_info->handler_flags == Alter_inplace_info::DROP_INDEX ||
ha_alter_info->handler_flags == Alter_inplace_info::DROP_UNIQUE_INDEX) {
error = alter_table_drop_index(altered_table, ha_alter_info);
} else
if (ha_alter_info->handler_flags & Alter_inplace_info::ADD_COLUMN ||
ha_alter_info->handler_flags & Alter_inplace_info::DROP_COLUMN) {
error = alter_table_add_or_drop_column(altered_table, ha_alter_info);
}
bool result = false; // success
if (error) {
print_error(error, MYF(0));
result = true; // failure
}
DBUG_RETURN(result);
}
int
ha_tokudb::alter_table_add_index(TABLE *altered_table, Alter_inplace_info *ha_alter_info) {
// TODO what does this do?
KEY *key_info = (KEY*) my_malloc(sizeof (KEY) * ha_alter_info->index_add_count, MYF(MY_WME));
KEY *key = key_info;
for (uint i = 0; i < ha_alter_info->index_add_count; i++) {
*key = ha_alter_info->key_info_buffer[ha_alter_info->index_add_buffer[i]];
for (KEY_PART_INFO *key_part= key->key_part; key_part < key->key_part + key->key_parts; key_part++)
key_part->field = table->field[key_part->fieldnr];
}
bool incremented_num_DBs = false;
bool modified_DBs = false;
int error = tokudb_add_index(table, key_info, ha_alter_info->index_add_count, transaction, &incremented_num_DBs, &modified_DBs);
if (error == HA_ERR_FOUND_DUPP_KEY) {
// hack for now, in case of duplicate key error,
// because at the moment we cannot display the right key
// information to the user, so that he knows potentially what went
// wrong.
last_dup_key = MAX_KEY;
}
assert(ha_alter_info->handler_ctx == NULL);
ha_alter_info->handler_ctx = new ha_tokudb_add_index_ctx(incremented_num_DBs, modified_DBs);
assert(ha_alter_info->handler_ctx);
my_free(key_info);
return error;
}
int
ha_tokudb::alter_table_drop_index(TABLE *altered_table, Alter_inplace_info *ha_alter_info) {
// translate KEY pointers to indexes into the key_info array
uint index_drop_offsets[ha_alter_info->index_drop_count];
for (uint i = 0; i < ha_alter_info->index_drop_count; i++)
index_drop_offsets[i] = ha_alter_info->index_drop_buffer[i] - table->key_info;
// drop indexes
int error = drop_indexes(table, index_drop_offsets, ha_alter_info->index_drop_count, transaction);
return error;
}
int
ha_tokudb::alter_table_add_or_drop_column(TABLE *altered_table, Alter_inplace_info *ha_alter_info) {
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);
u_int32_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;
memset(&altered_kc_info, 0, sizeof(altered_kc_info));
error = allocate_key_and_col_info(altered_table->s, &altered_kc_info);
if (error) { goto cleanup; }
max_new_desc_size = get_max_desc_size(&altered_kc_info, altered_table);
row_desc_buff = (uchar *)my_malloc(max_new_desc_size, MYF(MY_WME));
if (row_desc_buff == NULL){ error = ENOMEM; goto cleanup;}
error = initialize_key_and_col_info(
altered_table->s,
altered_table,
&altered_kc_info,
hidden_primary_key,
primary_key
);
if (error) { goto cleanup; }
// generate the array of columns
if (ha_alter_info->handler_flags & Alter_inplace_info::DROP_COLUMN) {
find_changed_columns(
columns,
&num_columns,
altered_table,
table
);
} else
if (ha_alter_info->handler_flags & Alter_inplace_info::ADD_COLUMN) {
find_changed_columns(
columns,
&num_columns,
table,
altered_table
);
} else
assert(0);
max_column_extra_size =
STATIC_ROW_MUTATOR_SIZE + //max static row_mutator
4 + num_columns*(1+1+4+1+1+4) + altered_table->s->reclength + // max dynamic row_mutator
(4 + share->kc_info.num_blobs) + // max static blob size
(num_columns*(1+4+1+4)); // max dynamic blob size
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++) {
DBT row_descriptor;
memset(&row_descriptor, 0, sizeof(row_descriptor));
KEY* prim_key = (hidden_primary_key) ? NULL : &altered_table->s->key_info[primary_key];
KEY* key_info = &altered_table->key_info[i];
if (i == primary_key) {
row_descriptor.size = create_main_key_descriptor(
row_desc_buff,
prim_key,
hidden_primary_key,
primary_key,
altered_table,
&altered_kc_info
);
row_descriptor.data = row_desc_buff;
}
else {
row_descriptor.size = create_secondary_key_descriptor(
row_desc_buff,
key_info,
prim_key,
hidden_primary_key,
altered_table,
primary_key,
i,
&altered_kc_info
);
row_descriptor.data = row_desc_buff;
}
error = share->key_file[i]->change_descriptor(
share->key_file[i],
transaction,
&row_descriptor,
0
);
if (error) { goto cleanup; }
if (i == primary_key || table_share->key_info[i].flags & HA_CLUSTERING) {
num_column_extra = fill_row_mutator(
column_extra,
columns,
num_columns,
altered_table,
&altered_kc_info,
i,
(ha_alter_info->handler_flags & Alter_inplace_info::ADD_COLUMN) != 0 // true if adding columns, otherwise is a drop
);
DBT column_dbt;
memset(&column_dbt, 0, sizeof column_dbt);
column_dbt.data = column_extra;
column_dbt.size = num_column_extra;
DBUG_ASSERT(num_column_extra <= max_column_extra_size);
error = share->key_file[i]->update_broadcast(
share->key_file[i],
transaction,
&column_dbt,
DB_IS_RESETTING_OP
);
if (error) { goto cleanup; }
}
}
error = 0;
cleanup:
free_key_and_col_info(&altered_kc_info);
my_free(row_desc_buff, MYF(MY_ALLOW_ZERO_PTR));
my_free(column_extra, MYF(MY_ALLOW_ZERO_PTR));
return error;
}
bool
ha_tokudb::commit_inplace_alter_table(TABLE *altered_table, Alter_inplace_info *ha_alter_info, bool commit) {
TOKUDB_DBUG_ENTER("commit_inplace_alter_table");
bool result = false; // success
if (commit) {
if (altered_table->part_info == NULL) {
// read frmdata for the altered table
uchar *frm_data; size_t frm_len;
int error = readfrm(altered_table->s->path.str, &frm_data, &frm_len);
if (error) {
result = true;
} else {
// transactionally write frmdata to status
assert(transaction);
error = write_to_status(share->status_block, hatoku_frm_data, (void *)frm_data, (uint)frm_len, transaction);
if (error) {
result = true;
}
my_free(frm_data);
}
if (error)
print_error(error, MYF(0));
}
}
if (!commit || result == true) {
if (ha_alter_info->handler_flags == Alter_inplace_info::ADD_INDEX ||
ha_alter_info->handler_flags == Alter_inplace_info::ADD_UNIQUE_INDEX) {
ha_tokudb_add_index_ctx *ctx = static_cast<ha_tokudb_add_index_ctx *>(ha_alter_info->handler_ctx);
assert(ctx);
restore_add_index(table, ha_alter_info->index_add_count, ctx->incremented_num_DBs, ctx->modified_DBs);
} else
if (ha_alter_info->handler_flags == Alter_inplace_info::DROP_INDEX ||
ha_alter_info->handler_flags == Alter_inplace_info::DROP_UNIQUE_INDEX) {
// translate KEY pointers to indexes into the key_info array
uint index_drop_offsets[ha_alter_info->index_drop_count];
for (uint i = 0; i < ha_alter_info->index_drop_count; i++)
index_drop_offsets[i] = ha_alter_info->index_drop_buffer[i] - table->key_info;
restore_drop_indexes(table, index_drop_offsets, ha_alter_info->index_drop_count);
}
}
DBUG_RETURN(result);
}
void
ha_tokudb::print_alter_info(TABLE *altered_table, Alter_inplace_info *ha_alter_info) {
printf("***are keys of two tables same? %d\n", tables_have_same_keys(table, altered_table, false, false));
if (ha_alter_info->handler_flags) {
printf("***alter flags set ***\n");
for (int i = 0; i < 32; i++) {
if (ha_alter_info->handler_flags & (1 << i))
printf("%d\n", i);
}
}
// everyone calculates data by doing some default_values - record[0], but I do not see why
// that is necessary
printf("******\n");
printf("***orig table***\n");
for (uint i = 0; i < table->s->fields; i++) {
//
// make sure to use table->field, and NOT table->s->field
//
Field* curr_field = table->field[i];
uint null_offset = get_null_offset(table, curr_field);
printf(
"name: %s, nullable: %d, null_offset: %d, is_null_field: %d, is_null %d, \n",
curr_field->field_name,
curr_field->null_bit,
null_offset,
(curr_field->null_ptr != NULL),
(curr_field->null_ptr != NULL) ? table->s->default_values[null_offset] & curr_field->null_bit : 0xffffffff
);
}
printf("******\n");
printf("***altered table***\n");
for (uint i = 0; i < altered_table->s->fields; i++) {
Field* curr_field = altered_table->field[i];
uint null_offset = get_null_offset(altered_table, curr_field);
printf(
"name: %s, nullable: %d, null_offset: %d, is_null_field: %d, is_null %d, \n",
curr_field->field_name,
curr_field->null_bit,
null_offset,
(curr_field->null_ptr != NULL),
(curr_field->null_ptr != NULL) ? altered_table->s->default_values[null_offset] & curr_field->null_bit : 0xffffffff
);
}
printf("******\n");
}
#endif
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