Commit a7135ea3 authored by marko's avatar marko

branches/zip: Fix a bug in the updates of index records that contain a

column prefix of an externally stored column.

row_upd_ext_fetch(): New function.

row_upd_index_replace_new_col_vals(),
row_upd_index_replace_new_col_vals_index_pos(): Fetch prefixes of
externally stored columns when they are needed for column prefix
indexes.  For memory allocation, add the parameter ext_heap.  Avoid
repeating the inner loop after finding a  matching upd_field->field_no.
parent 2080273e
...@@ -1860,7 +1860,7 @@ any_extern: ...@@ -1860,7 +1860,7 @@ any_extern:
ut_a(!n_ext); ut_a(!n_ext);
row_upd_index_replace_new_col_vals_index_pos(new_entry, index, update, row_upd_index_replace_new_col_vals_index_pos(new_entry, index, update,
FALSE, NULL); FALSE, NULL, heap);
old_rec_size = rec_offs_size(offsets); old_rec_size = rec_offs_size(offsets);
new_rec_size = rec_get_converted_size(index, new_entry, 0); new_rec_size = rec_get_converted_size(index, new_entry, 0);
...@@ -2131,7 +2131,7 @@ btr_cur_pessimistic_update( ...@@ -2131,7 +2131,7 @@ btr_cur_pessimistic_update(
rec_offs_make_valid(rec, index, offsets); rec_offs_make_valid(rec, index, offsets);
row_upd_index_replace_new_col_vals_index_pos(new_entry, index, update, row_upd_index_replace_new_col_vals_index_pos(new_entry, index, update,
FALSE, *heap); FALSE, *heap, *heap);
if (!(flags & BTR_KEEP_SYS_FLAG)) { if (!(flags & BTR_KEEP_SYS_FLAG)) {
row_upd_index_entry_sys_field(new_entry, index, DATA_ROLL_PTR, row_upd_index_entry_sys_field(new_entry, index, DATA_ROLL_PTR,
roll_ptr); roll_ptr);
......
...@@ -195,9 +195,14 @@ row_upd_index_replace_new_col_vals_index_pos( ...@@ -195,9 +195,14 @@ row_upd_index_replace_new_col_vals_index_pos(
/* in: if TRUE, limit the replacement to /* in: if TRUE, limit the replacement to
ordering fields of index; note that this ordering fields of index; note that this
does not work for non-clustered indexes. */ does not work for non-clustered indexes. */
mem_heap_t* heap); /* in: memory heap to which we allocate and mem_heap_t* heap, /* in: memory heap to which we allocate and
copy the new values, set this as NULL if you copy the new values, set this as NULL if you
do not want allocation */ do not want allocation */
mem_heap_t* ext_heap);/* in: memory heap where to allocate
column prefixes of externally stored
columns, may be NULL if the index
record does not contain externally
stored columns or column prefixes */
/*************************************************************** /***************************************************************
Replaces the new column values stored in the update vector to the index entry Replaces the new column values stored in the update vector to the index entry
given. */ given. */
...@@ -211,9 +216,14 @@ row_upd_index_replace_new_col_vals( ...@@ -211,9 +216,14 @@ row_upd_index_replace_new_col_vals(
const upd_t* update, /* in: an update vector built for the const upd_t* update, /* in: an update vector built for the
CLUSTERED index so that the field number in CLUSTERED index so that the field number in
an upd_field is the clustered index position */ an upd_field is the clustered index position */
mem_heap_t* heap); /* in: memory heap to which we allocate and mem_heap_t* heap, /* in: memory heap to which we allocate and
copy the new values, set this as NULL if you copy the new values, set this as NULL if you
do not want allocation */ do not want allocation */
mem_heap_t* ext_heap);/* in: memory heap where to allocate
column prefixes of externally stored
columns, may be NULL if the index
record does not contain externally
stored columns or column prefixes */
/*************************************************************** /***************************************************************
Checks if an update vector changes an ordering field of an index record. Checks if an update vector changes an ordering field of an index record.
This function is fast if the update vector is short or the number of ordering This function is fast if the update vector is short or the number of ordering
......
...@@ -638,7 +638,8 @@ row_undo_mod_upd_exist_sec( ...@@ -638,7 +638,8 @@ row_undo_mod_upd_exist_sec(
'abc' -> 'aBc'. */ 'abc' -> 'aBc'. */
row_upd_index_replace_new_col_vals(entry, index, row_upd_index_replace_new_col_vals(entry, index,
node->update, NULL); node->update,
NULL, heap);
err = row_undo_mod_del_unmark_sec_and_undo_update( err = row_undo_mod_del_unmark_sec_and_undo_update(
BTR_MODIFY_LEAF, thr, index, entry); BTR_MODIFY_LEAF, thr, index, entry);
if (err == DB_FAIL) { if (err == DB_FAIL) {
......
...@@ -832,6 +832,35 @@ skip_compare: ...@@ -832,6 +832,35 @@ skip_compare:
return(update); return(update);
} }
/***************************************************************
Fetch a prefix of an externally stored column. This is similar
to row_ext_lookup(), but the row_ext_t holds the old values
of the column and must not be poisoned with the new values. */
static
byte*
row_upd_ext_fetch(
/*==============*/
/* out: BLOB prefix */
const byte* data, /* in: 'internally' stored part of the
field containing also the reference to
the external part */
ulint local_len, /* in: length of data, in bytes */
ulint zip_size, /* in: nonzero=compressed BLOB
page size, zero for uncompressed
BLOBs */
ulint* len, /* in: length of prefix to fetch;
out: fetched length of the prefix */
mem_heap_t* heap) /* in: heap where to allocate */
{
byte* buf = mem_heap_alloc(heap, *len);
*len = btr_copy_externally_stored_field_prefix(buf, *len,
zip_size,
data, local_len);
return(buf);
}
/*************************************************************** /***************************************************************
Replaces the new column values stored in the update vector to the index entry Replaces the new column values stored in the update vector to the index entry
given. */ given. */
...@@ -849,13 +878,15 @@ row_upd_index_replace_new_col_vals_index_pos( ...@@ -849,13 +878,15 @@ row_upd_index_replace_new_col_vals_index_pos(
/* in: if TRUE, limit the replacement to /* in: if TRUE, limit the replacement to
ordering fields of index; note that this ordering fields of index; note that this
does not work for non-clustered indexes. */ does not work for non-clustered indexes. */
mem_heap_t* heap) /* in: memory heap to which we allocate and mem_heap_t* heap, /* in: memory heap to which we allocate and
copy the new values, set this as NULL if you copy the new values, set this as NULL if you
do not want allocation */ do not want allocation */
mem_heap_t* ext_heap)/* in: memory heap where to allocate
column prefixes of externally stored
columns, may be NULL if the index
record does not contain externally
stored columns or column prefixes */
{ {
dict_field_t* field;
upd_field_t* upd_field;
dfield_t* dfield;
ulint j; ulint j;
ulint i; ulint i;
ulint n_fields; ulint n_fields;
...@@ -872,44 +903,78 @@ row_upd_index_replace_new_col_vals_index_pos( ...@@ -872,44 +903,78 @@ row_upd_index_replace_new_col_vals_index_pos(
for (j = 0; j < n_fields; j++) { for (j = 0; j < n_fields; j++) {
field = dict_index_get_nth_field(index, j); dict_field_t* field
= dict_index_get_nth_field(index, j);
const dict_col_t* col
= dict_field_get_col(field);
for (i = 0; i < upd_get_n_fields(update); i++) { for (i = 0; i < upd_get_n_fields(update); i++) {
upd_field_t* upd_field;
dfield_t* dfield;
upd_field = upd_get_nth_field(update, i); upd_field = upd_get_nth_field(update, i);
if (upd_field->field_no == j) { if (upd_field->field_no != j) {
continue;
}
dfield = dtuple_get_nth_field(entry, j); dfield = dtuple_get_nth_field(entry, j);
dfield_copy_data(dfield, &upd_field->new_val); dfield_copy_data(dfield, &upd_field->new_val);
if (dfield_is_null(dfield)) { if (dfield_is_null(dfield)) {
continue; break;
} }
if (heap) { if (field->prefix_len > 0) {
dfield_dup(dfield, heap); ulint len
= dfield_get_len(dfield);
const char* data
= dfield_get_data(dfield);
ibool fetch_ext
= dfield_is_ext(dfield)
&& len < field->prefix_len
+ BTR_EXTERN_FIELD_REF_SIZE;
if (fetch_ext) {
ulint l
= len;
ulint zip_size
= dict_table_zip_size(
index->table);
ut_a(ext_heap);
len = field->prefix_len;
data = row_upd_ext_fetch(data, l,
zip_size,
&len,
ext_heap);
} }
if (field->prefix_len > 0) { len = dtype_get_at_most_n_mbchars(
col->prtype,
col->mbminlen,
col->mbmaxlen,
field->prefix_len,
len, data);
const dict_col_t* col dfield_set_data(dfield, data, len);
= dict_field_get_col(field);
ulint len
= dfield_get_len(dfield);
len = dtype_get_at_most_n_mbchars( if (fetch_ext && heap && heap == ext_heap) {
col->prtype, /* Skip the dfield_dup() below,
col->mbminlen, as the column prefix has already
col->mbmaxlen, been allocated from ext_heap. */
field->prefix_len, break;
len,
dfield_get_data(dfield));
dfield_set_len(dfield, len);
} }
} }
if (heap) {
dfield_dup(dfield, heap);
}
break;
} }
} }
} }
...@@ -927,12 +992,15 @@ row_upd_index_replace_new_col_vals( ...@@ -927,12 +992,15 @@ row_upd_index_replace_new_col_vals(
const upd_t* update, /* in: an update vector built for the const upd_t* update, /* in: an update vector built for the
CLUSTERED index so that the field number in CLUSTERED index so that the field number in
an upd_field is the clustered index position */ an upd_field is the clustered index position */
mem_heap_t* heap) /* in: memory heap to which we allocate and mem_heap_t* heap, /* in: memory heap to which we allocate and
copy the new values, set this as NULL if you copy the new values, set this as NULL if you
do not want allocation */ do not want allocation */
mem_heap_t* ext_heap)/* in: memory heap where to allocate
column prefixes of externally stored
columns, may be NULL if the index
record does not contain externally
stored columns or column prefixes */
{ {
upd_field_t* upd_field;
dfield_t* dfield;
ulint j; ulint j;
ulint i; ulint i;
dict_index_t* clust_index; dict_index_t* clust_index;
...@@ -945,47 +1013,78 @@ row_upd_index_replace_new_col_vals( ...@@ -945,47 +1013,78 @@ row_upd_index_replace_new_col_vals(
for (j = 0; j < dict_index_get_n_fields(index); j++) { for (j = 0; j < dict_index_get_n_fields(index); j++) {
ulint clust_pos; dict_field_t* field
dict_field_t* field = dict_index_get_nth_field(index, j); = dict_index_get_nth_field(index, j);
const dict_col_t* col
clust_pos = dict_col_get_clust_pos(field->col, clust_index); = dict_field_get_col(field);
const ulint clust_pos
= dict_col_get_clust_pos(col, clust_index);
for (i = 0; i < upd_get_n_fields(update); i++) { for (i = 0; i < upd_get_n_fields(update); i++) {
upd_field_t* upd_field;
dfield_t* dfield;
upd_field = upd_get_nth_field(update, i); upd_field = upd_get_nth_field(update, i);
if (upd_field->field_no == clust_pos) { if (upd_field->field_no != clust_pos) {
continue;
}
dfield = dtuple_get_nth_field(entry, j); dfield = dtuple_get_nth_field(entry, j);
dfield_copy_data(dfield, &upd_field->new_val); dfield_copy_data(dfield, &upd_field->new_val);
if (dfield_is_null(dfield)) { if (dfield_is_null(dfield)) {
continue; break;
} }
if (heap) { if (field->prefix_len > 0) {
dfield_dup(dfield, heap); ulint len
= dfield_get_len(dfield);
const char* data
= dfield_get_data(dfield);
if (dfield_is_ext(dfield)
&& len < field->prefix_len
+ BTR_EXTERN_FIELD_REF_SIZE) {
ulint l
= len;
ulint zip_size
= dict_table_zip_size(
index->table);
ut_a(ext_heap);
len = field->prefix_len;
data = row_upd_ext_fetch(data, l,
zip_size,
&len,
ext_heap);
} }
if (field->prefix_len > 0) { len = dtype_get_at_most_n_mbchars(
col->prtype,
const dict_col_t* col col->mbminlen,
= dict_field_get_col(field); col->mbmaxlen,
ulint len field->prefix_len,
= dfield_get_len(dfield); len, data);
len = dtype_get_at_most_n_mbchars( dfield_set_data(dfield, data, len);
col->prtype,
col->mbminlen,
col->mbmaxlen,
field->prefix_len,
len,
dfield_get_data(dfield));
dfield_set_len(dfield, len); if (fetch_ext && heap && heap == ext_heap) {
/* Skip the dfield_dup() below,
as the column prefix has already
been allocated from ext_heap. */
break;
} }
} }
if (heap) {
dfield_dup(dfield, heap);
}
break;
} }
} }
} }
...@@ -1338,7 +1437,8 @@ row_upd_sec_index_entry( ...@@ -1338,7 +1437,8 @@ row_upd_sec_index_entry(
} }
/* Build a new index entry */ /* Build a new index entry */
row_upd_index_replace_new_col_vals(entry, index, node->update, NULL); row_upd_index_replace_new_col_vals(entry, index, node->update,
NULL, heap);
/* Insert new index entry */ /* Insert new index entry */
err = row_ins_index_entry(index, entry, 0, TRUE, thr); err = row_ins_index_entry(index, entry, 0, TRUE, thr);
...@@ -1458,7 +1558,8 @@ row_upd_clust_rec_by_insert( ...@@ -1458,7 +1558,8 @@ row_upd_clust_rec_by_insert(
entry = row_build_index_entry(node->row, node->ext, index, heap); entry = row_build_index_entry(node->row, node->ext, index, heap);
row_upd_index_replace_new_col_vals(entry, index, node->update, NULL); row_upd_index_replace_new_col_vals(entry, index, node->update,
NULL, heap);
row_upd_index_entry_sys_field(entry, index, DATA_TRX_ID, trx->id); row_upd_index_entry_sys_field(entry, index, DATA_TRX_ID, trx->id);
......
...@@ -1413,7 +1413,8 @@ trx_undo_prev_version_build( ...@@ -1413,7 +1413,8 @@ trx_undo_prev_version_build(
entry = row_rec_to_index_entry(ROW_COPY_DATA, rec, index, entry = row_rec_to_index_entry(ROW_COPY_DATA, rec, index,
offsets, &n_ext, heap); offsets, &n_ext, heap);
n_ext += btr_push_update_extern_fields(entry, update); n_ext += btr_push_update_extern_fields(entry, update);
row_upd_index_replace_new_col_vals(entry, index, update, heap); row_upd_index_replace_new_col_vals(entry, index, update,
heap, heap);
buf = mem_heap_alloc(heap, rec_get_converted_size(index, entry, buf = mem_heap_alloc(heap, rec_get_converted_size(index, entry,
n_ext)); n_ext));
......
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