Commit a5e7b6ac authored by Yoni Fogel's avatar Yoni Fogel

Refs Tokutek/ft-index#46 Rename dmt_size->num_klpairs, dmt_iterate*->iterate*

parent 4d3451ac
......@@ -186,7 +186,7 @@ void bn_data::serialize_to_wbuf(struct wbuf *const wb) {
//
// iterate over leafentries and place them into the buffer
//
dmt_iterate<struct wbuf, wbufwriteleafentry>(wb);
iterate<struct wbuf, wbufwriteleafentry>(wb);
}
}
......@@ -552,7 +552,7 @@ void bn_data::split_klpairs(
{
// We use move_leafentries_to during a split, and the split algorithm should never call this
// if it's splitting on a boundary, so there must be some leafentries in the range to move.
paranoid_invariant(split_at < dmt_size());
paranoid_invariant(split_at < num_klpairs());
right_bd->init_zero();
......@@ -568,7 +568,7 @@ void bn_data::split_klpairs(
left_dmt_builder.create(split_at, m_disksize_of_keys); // overkill, but safe (builder will realloc at the end)
klpair_dmt_t::builder right_dmt_builder;
right_dmt_builder.create(dmt_size() - split_at, m_disksize_of_keys); // overkill, but safe (builder will realloc at the end)
right_dmt_builder.create(num_klpairs() - split_at, m_disksize_of_keys); // overkill, but safe (builder will realloc at the end)
split_klpairs_extra extra(this, right_bd, &left_dmt_builder, &right_dmt_builder, &new_left_mp, split_at);
......@@ -625,7 +625,7 @@ void bn_data::verify_mempool(void) {
m_buffer.iterate_ptr< decltype(state), verify_le_in_mempool >(&state);
}
uint32_t bn_data::dmt_size(void) const {
uint32_t bn_data::num_klpairs(void) const {
return m_buffer.size();
}
......@@ -648,7 +648,7 @@ void bn_data::set_contents_as_clone_of_sorted_array(
{
//Enforce "just created" invariant.
paranoid_invariant_zero(m_disksize_of_keys);
paranoid_invariant_zero(dmt_size());
paranoid_invariant_zero(num_klpairs());
paranoid_invariant_null(toku_mempool_get_base(&m_buffer_mempool));
paranoid_invariant_zero(toku_mempool_get_size(&m_buffer_mempool));
......
......@@ -193,22 +193,19 @@ class bn_data {
void verify_mempool(void);
// size() of key dmt
// TODO(yoni): maybe rename to something like num_klpairs
uint32_t dmt_size(void) const;
uint32_t num_klpairs(void) const;
// iterate() on key dmt (and associated leafentries)
// TODO(yoni): rename to iterate
template<typename iterate_extra_t,
int (*f)(const void * key, const uint32_t keylen, const LEAFENTRY &, const uint32_t, iterate_extra_t *const)>
int dmt_iterate(iterate_extra_t *const iterate_extra) const {
return dmt_iterate_on_range<iterate_extra_t, f>(0, dmt_size(), iterate_extra);
int iterate(iterate_extra_t *const iterate_extra) const {
return iterate_on_range<iterate_extra_t, f>(0, num_klpairs(), iterate_extra);
}
// iterate_on_range() on key dmt (and associated leafentries)
// TODO(yoni): rename to iterate_on_range
template<typename iterate_extra_t,
int (*f)(const void * key, const uint32_t keylen, const LEAFENTRY &, const uint32_t, iterate_extra_t *const)>
int dmt_iterate_on_range(const uint32_t left, const uint32_t right, iterate_extra_t *const iterate_extra) const {
int iterate_on_range(const uint32_t left, const uint32_t right, iterate_extra_t *const iterate_extra) const {
klpair_iterate_extra<iterate_extra_t> klpair_extra = { iterate_extra, this };
return m_buffer.iterate_on_range< klpair_iterate_extra<iterate_extra_t>, klpair_iterate_wrapper<iterate_extra_t, f> >(left, right, &klpair_extra);
}
......
......@@ -689,16 +689,16 @@ ftleaf_get_split_loc(
switch (split_mode) {
case SPLIT_LEFT_HEAVY: {
*num_left_bns = node->n_children;
*num_left_les = BLB_DATA(node, *num_left_bns - 1)->dmt_size();
*num_left_les = BLB_DATA(node, *num_left_bns - 1)->num_klpairs();
if (*num_left_les == 0) {
*num_left_bns = node->n_children - 1;
*num_left_les = BLB_DATA(node, *num_left_bns - 1)->dmt_size();
*num_left_les = BLB_DATA(node, *num_left_bns - 1)->num_klpairs();
}
goto exit;
}
case SPLIT_RIGHT_HEAVY: {
*num_left_bns = 1;
*num_left_les = BLB_DATA(node, 0)->dmt_size() ? 1 : 0;
*num_left_les = BLB_DATA(node, 0)->num_klpairs() ? 1 : 0;
goto exit;
}
case SPLIT_EVENLY: {
......@@ -708,7 +708,7 @@ ftleaf_get_split_loc(
uint32_t size_so_far = 0;
for (int i = 0; i < node->n_children; i++) {
bn_data* bd = BLB_DATA(node, i);
uint32_t n_leafentries = bd->dmt_size();
uint32_t n_leafentries = bd->num_klpairs();
for (uint32_t j=0; j < n_leafentries; j++) {
size_t size_this_le;
int rr = bd->fetch_klpair_disksize(j, &size_this_le);
......@@ -725,7 +725,7 @@ ftleaf_get_split_loc(
(*num_left_les)--;
} else if (*num_left_bns > 1) {
(*num_left_bns)--;
*num_left_les = BLB_DATA(node, *num_left_bns - 1)->dmt_size();
*num_left_les = BLB_DATA(node, *num_left_bns - 1)->num_klpairs();
} else {
// we are trying to split a leaf with only one
// leafentry in it
......@@ -754,7 +754,7 @@ move_leafentries(
)
//Effect: move leafentries in the range [lbi, upe) from src_omt to newly created dest_omt
{
invariant(ube == src_bn->data_buffer.dmt_size());
invariant(ube == src_bn->data_buffer.num_klpairs());
src_bn->data_buffer.split_klpairs(&dest_bn->data_buffer, lbi);
}
......@@ -852,7 +852,7 @@ ftleaf_split(
ftleaf_get_split_loc(node, split_mode, &num_left_bns, &num_left_les);
{
// did we split right on the boundary between basement nodes?
const bool split_on_boundary = (num_left_les == 0) || (num_left_les == (int) BLB_DATA(node, num_left_bns - 1)->dmt_size());
const bool split_on_boundary = (num_left_les == 0) || (num_left_les == (int) BLB_DATA(node, num_left_bns - 1)->num_klpairs());
// Now we know where we are going to break it
// the two nodes will have a total of n_children+1 basement nodes
// and n_children-1 pivots
......@@ -913,7 +913,7 @@ ftleaf_split(
move_leafentries(BLB(B, curr_dest_bn_index),
BLB(node, curr_src_bn_index),
num_left_les, // first row to be moved to B
BLB_DATA(node, curr_src_bn_index)->dmt_size() // number of rows in basement to be split
BLB_DATA(node, curr_src_bn_index)->num_klpairs() // number of rows in basement to be split
);
BLB_MAX_MSN_APPLIED(B, curr_dest_bn_index) = BLB_MAX_MSN_APPLIED(node, curr_src_bn_index);
curr_dest_bn_index++;
......@@ -958,7 +958,7 @@ ftleaf_split(
bn_data* bd = BLB_DATA(node, num_left_bns - 1);
uint32_t keylen;
void *key;
int rr = bd->fetch_key_and_len(bd->dmt_size() - 1, &keylen, &key);
int rr = bd->fetch_key_and_len(bd->num_klpairs() - 1, &keylen, &key);
invariant_zero(rr);
toku_memdup_dbt(splitk, key, keylen);
}
......@@ -1173,7 +1173,7 @@ merge_leaf_nodes(FTNODE a, FTNODE b)
// this bool states if the last basement node in a has any items or not
// If it does, then it stays in the merge. If it does not, the last basement node
// of a gets eliminated because we do not have a pivot to store for it (because it has no elements)
const bool a_has_tail = a_last_bd->dmt_size() > 0;
const bool a_has_tail = a_last_bd->num_klpairs() > 0;
// move each basement node from b to a
// move the pivots, adding one of what used to be max(a)
......@@ -1200,7 +1200,7 @@ merge_leaf_nodes(FTNODE a, FTNODE b)
if (a_has_tail) {
uint32_t keylen;
void *key;
int rr = a_last_bd->fetch_key_and_len(a_last_bd->dmt_size() - 1, &keylen, &key);
int rr = a_last_bd->fetch_key_and_len(a_last_bd->num_klpairs() - 1, &keylen, &key);
invariant_zero(rr);
toku_memdup_dbt(&a->childkeys[a->n_children-1], key, keylen);
a->totalchildkeylens += keylen;
......
......@@ -419,7 +419,7 @@ get_leaf_num_entries(FTNODE node) {
int i;
toku_assert_entire_node_in_memory(node);
for ( i = 0; i < node->n_children; i++) {
result += BLB_DATA(node, i)->dmt_size();
result += BLB_DATA(node, i)->num_klpairs();
}
return result;
}
......@@ -1910,7 +1910,7 @@ toku_ft_bn_apply_cmd (
void* key = NULL;
uint32_t keylen = 0;
uint32_t dmt_size;
uint32_t num_klpairs;
int r;
struct cmd_leafval_heaviside_extra be = {compare_fun, desc, cmd->u.id.key};
......@@ -1922,7 +1922,7 @@ toku_ft_bn_apply_cmd (
case FT_INSERT: {
uint32_t idx;
if (doing_seqinsert) {
idx = bn->data_buffer.dmt_size();
idx = bn->data_buffer.num_klpairs();
DBT kdbt;
r = bn->data_buffer.fetch_key_and_len(idx-1, &kdbt.size, &kdbt.data);
if (r != 0) goto fz;
......@@ -1950,7 +1950,7 @@ toku_ft_bn_apply_cmd (
// the leaf then it is sequential
// window = min(32, number of leaf entries/16)
{
uint32_t s = bn->data_buffer.dmt_size();
uint32_t s = bn->data_buffer.num_klpairs();
uint32_t w = s / 16;
if (w == 0) w = 1;
if (w > 32) w = 32;
......@@ -1985,8 +1985,8 @@ toku_ft_bn_apply_cmd (
case FT_COMMIT_BROADCAST_ALL:
case FT_OPTIMIZE:
// Apply to all leafentries
dmt_size = bn->data_buffer.dmt_size();
for (uint32_t idx = 0; idx < dmt_size; ) {
num_klpairs = bn->data_buffer.num_klpairs();
for (uint32_t idx = 0; idx < num_klpairs; ) {
DBT curr_keydbt;
void* curr_keyp = NULL;
uint32_t curr_keylen = 0;
......@@ -2000,26 +2000,26 @@ toku_ft_bn_apply_cmd (
if (!le_is_clean(storeddata)) { //If already clean, nothing to do.
toku_ft_bn_apply_cmd_once(bn, cmd, idx, storeddata, oldest_referenced_xid_known, gc_info, workdone, stats_to_update);
// at this point, we cannot trust cmd->u.id.key to be valid.
uint32_t new_dmt_size = bn->data_buffer.dmt_size();
if (new_dmt_size != dmt_size) {
paranoid_invariant(new_dmt_size+1 == dmt_size);
uint32_t new_dmt_size = bn->data_buffer.num_klpairs();
if (new_dmt_size != num_klpairs) {
paranoid_invariant(new_dmt_size+1 == num_klpairs);
//Item was deleted.
deleted = 1;
}
}
if (deleted)
dmt_size--;
num_klpairs--;
else
idx++;
}
paranoid_invariant(bn->data_buffer.dmt_size() == dmt_size);
paranoid_invariant(bn->data_buffer.num_klpairs() == num_klpairs);
break;
case FT_COMMIT_BROADCAST_TXN:
case FT_ABORT_BROADCAST_TXN:
// Apply to all leafentries if txn is represented
dmt_size = bn->data_buffer.dmt_size();
for (uint32_t idx = 0; idx < dmt_size; ) {
num_klpairs = bn->data_buffer.num_klpairs();
for (uint32_t idx = 0; idx < num_klpairs; ) {
DBT curr_keydbt;
void* curr_keyp = NULL;
uint32_t curr_keylen = 0;
......@@ -2032,19 +2032,19 @@ toku_ft_bn_apply_cmd (
int deleted = 0;
if (le_has_xids(storeddata, cmd->xids)) {
toku_ft_bn_apply_cmd_once(bn, cmd, idx, storeddata, oldest_referenced_xid_known, gc_info, workdone, stats_to_update);
uint32_t new_dmt_size = bn->data_buffer.dmt_size();
if (new_dmt_size != dmt_size) {
paranoid_invariant(new_dmt_size+1 == dmt_size);
uint32_t new_dmt_size = bn->data_buffer.num_klpairs();
if (new_dmt_size != num_klpairs) {
paranoid_invariant(new_dmt_size+1 == num_klpairs);
//Item was deleted.
deleted = 1;
}
}
if (deleted)
dmt_size--;
num_klpairs--;
else
idx++;
}
paranoid_invariant(bn->data_buffer.dmt_size() == dmt_size);
paranoid_invariant(bn->data_buffer.num_klpairs() == num_klpairs);
break;
case FT_UPDATE: {
......@@ -2073,7 +2073,7 @@ toku_ft_bn_apply_cmd (
// apply to all leafentries.
uint32_t idx = 0;
uint32_t num_leafentries_before;
while (idx < (num_leafentries_before = bn->data_buffer.dmt_size())) {
while (idx < (num_leafentries_before = bn->data_buffer.num_klpairs())) {
void* curr_key = nullptr;
uint32_t curr_keylen = 0;
r = bn->data_buffer.fetch_klpair(idx, &storeddata, &curr_keylen, &curr_key);
......@@ -2091,7 +2091,7 @@ toku_ft_bn_apply_cmd (
r = do_update(update_fun, desc, bn, cmd, idx, storeddata, curr_key, curr_keylen, oldest_referenced_xid_known, gc_info, workdone, stats_to_update);
assert_zero(r);
if (num_leafentries_before == bn->data_buffer.dmt_size()) {
if (num_leafentries_before == bn->data_buffer.num_klpairs()) {
// we didn't delete something, so increment the index.
idx++;
}
......@@ -2404,7 +2404,7 @@ basement_node_gc_all_les(BASEMENTNODE bn,
int r = 0;
uint32_t index = 0;
uint32_t num_leafentries_before;
while (index < (num_leafentries_before = bn->data_buffer.dmt_size())) {
while (index < (num_leafentries_before = bn->data_buffer.num_klpairs())) {
void* keyp = NULL;
uint32_t keylen = 0;
LEAFENTRY leaf_entry;
......@@ -2423,7 +2423,7 @@ basement_node_gc_all_les(BASEMENTNODE bn,
delta
);
// Check if the leaf entry was deleted or not.
if (num_leafentries_before == bn->data_buffer.dmt_size()) {
if (num_leafentries_before == bn->data_buffer.num_klpairs()) {
++index;
}
}
......@@ -4929,7 +4929,7 @@ ok: ;
switch (search->direction) {
case FT_SEARCH_LEFT:
idx++;
if (idx >= bn->data_buffer.dmt_size()) {
if (idx >= bn->data_buffer.num_klpairs()) {
if (ftcursor->interrupt_cb && ftcursor->interrupt_cb(ftcursor->interrupt_cb_extra)) {
return TOKUDB_INTERRUPTED;
}
......@@ -5604,7 +5604,7 @@ ft_cursor_shortcut (
int r = 0;
// if we are searching towards the end, limit is last element
// if we are searching towards the beginning, limit is the first element
uint32_t limit = (direction > 0) ? (bd->dmt_size() - 1) : 0;
uint32_t limit = (direction > 0) ? (bd->num_klpairs() - 1) : 0;
//Starting with the prev, find the first real (non-provdel) leafentry.
while (index != limit) {
......@@ -5895,7 +5895,7 @@ keysrange_in_leaf_partition (FT_HANDLE brt, FTNODE node,
*less = idx_left;
*equal_left = (r==0) ? 1 : 0;
uint32_t size = bn->data_buffer.dmt_size();
uint32_t size = bn->data_buffer.num_klpairs();
uint32_t idx_right = size;
r = -1;
if (single_basement && key_right) {
......@@ -6155,7 +6155,7 @@ static int get_key_after_bytes_in_basementnode(FT ft, BASEMENTNODE bn, const DBT
assert(r == 0 || r == DB_NOTFOUND);
}
struct get_key_after_bytes_iterate_extra iter_extra = {skip_len, skipped, callback, cb_extra};
r = bn->data_buffer.dmt_iterate_on_range<get_key_after_bytes_iterate_extra, get_key_after_bytes_iterate>(idx_left, bn->data_buffer.dmt_size(), &iter_extra);
r = bn->data_buffer.iterate_on_range<get_key_after_bytes_iterate_extra, get_key_after_bytes_iterate>(idx_left, bn->data_buffer.num_klpairs(), &iter_extra);
// Invert the sense of r == 0 (meaning the iterate finished, which means we didn't find what we wanted)
if (r == 1) {
......@@ -6351,7 +6351,7 @@ toku_dump_ftnode (FILE *file, FT_HANDLE brt, BLOCKNUM blocknum, int depth, const
});
}
else {
int size = BLB_DATA(node, i)->dmt_size();
int size = BLB_DATA(node, i)->num_klpairs();
if (0)
for (int j=0; j<size; j++) {
LEAFENTRY le;
......@@ -6533,7 +6533,7 @@ static bool is_empty_fast_iter (FT_HANDLE brt, FTNODE node) {
} else {
// leaf: If the dmt is empty, we are happy.
for (int i = 0; i < node->n_children; i++) {
if (BLB_DATA(node, i)->dmt_size()) {
if (BLB_DATA(node, i)->num_klpairs()) {
return false;
}
}
......
......@@ -424,7 +424,7 @@ toku_verify_ftnode_internal(FT_HANDLE brt,
}
else {
BASEMENTNODE bn = BLB(node, i);
for (uint32_t j = 0; j < bn->data_buffer.dmt_size(); j++) {
for (uint32_t j = 0; j < bn->data_buffer.num_klpairs(); j++) {
VERIFY_ASSERTION((rootmsn.msn >= this_msn.msn), 0, "leaf may have latest msn, but cannot be greater than root msn");
DBT kdbt = get_ith_key_dbt(bn, j);
if (curr_less_pivot) {
......
......@@ -1078,7 +1078,7 @@ garbage_helper(BLOCKNUM blocknum, int64_t UU(size), int64_t UU(address), void *e
}
for (int i = 0; i < node->n_children; ++i) {
bn_data* bd = BLB_DATA(node, i);
r = bd->dmt_iterate<struct garbage_helper_extra, garbage_leafentry_helper>(info);
r = bd->iterate<struct garbage_helper_extra, garbage_leafentry_helper>(info);
if (r != 0) {
goto exit;
}
......
......@@ -353,7 +353,7 @@ serialize_ftnode_partition(FTNODE node, int i, struct sub_block *sb) {
bn_data* bd = BLB_DATA(node, i);
wbuf_nocrc_char(&wb, ch);
wbuf_nocrc_uint(&wb, bd->dmt_size());
wbuf_nocrc_uint(&wb, bd->num_klpairs());
bd->serialize_to_wbuf(&wb);
}
......@@ -518,7 +518,7 @@ rebalance_ftnode_leaf(FTNODE node, unsigned int basementnodesize)
// Count number of leaf entries in this leaf (num_le).
uint32_t num_le = 0;
for (uint32_t i = 0; i < num_orig_basements; i++) {
num_le += BLB_DATA(node, i)->dmt_size();
num_le += BLB_DATA(node, i)->num_klpairs();
}
uint32_t num_alloc = num_le ? num_le : 1; // simplify logic below by always having at least one entry per array
......@@ -545,8 +545,8 @@ rebalance_ftnode_leaf(FTNODE node, unsigned int basementnodesize)
for (uint32_t i = 0; i < num_orig_basements; i++) {
bn_data* bd = BLB_DATA(node, i);
struct array_info ai {.offset = curr_le, .le_array = leafpointers, .key_sizes_array = key_sizes, .key_ptr_array = key_pointers };
bd->dmt_iterate<array_info, array_item>(&ai);
curr_le += bd->dmt_size();
bd->iterate<array_info, array_item>(&ai);
curr_le += bd->num_klpairs();
}
// Create an array that will store indexes of new pivots.
......
......@@ -2917,7 +2917,7 @@ static void add_pair_to_leafnode (struct leaf_buf *lbuf, unsigned char *key, int
// #3588 TODO just make a clean ule and append it to the omt
// #3588 TODO can do the rebalancing here and avoid a lot of work later
FTNODE leafnode = lbuf->node;
uint32_t idx = BLB_DATA(leafnode, 0)->dmt_size();
uint32_t idx = BLB_DATA(leafnode, 0)->num_klpairs();
DBT thekey = { .data = key, .size = (uint32_t) keylen };
DBT theval = { .data = val, .size = (uint32_t) vallen };
FT_MSG_S cmd = { .type = FT_INSERT,
......
......@@ -362,7 +362,7 @@ test_serialize_leaf_check_msn(enum ftnode_verify_type bft, bool do_clone) {
if (bn > 0) {
assert(dest_ndd[bn].start >= dest_ndd[bn-1].start + dest_ndd[bn-1].size);
}
for (uint32_t i = 0; i < BLB_DATA(dn, bn)->dmt_size(); i++) {
for (uint32_t i = 0; i < BLB_DATA(dn, bn)->num_klpairs(); i++) {
LEAFENTRY curr_le;
uint32_t curr_keylen;
void* curr_key;
......@@ -504,8 +504,8 @@ test_serialize_leaf_with_large_pivots(enum ftnode_verify_type bft, bool do_clone
if (bn > 0) {
assert(dest_ndd[bn].start >= dest_ndd[bn-1].start + dest_ndd[bn-1].size);
}
assert(BLB_DATA(dn, bn)->dmt_size() > 0);
for (uint32_t i = 0; i < BLB_DATA(dn, bn)->dmt_size(); i++) {
assert(BLB_DATA(dn, bn)->num_klpairs() > 0);
for (uint32_t i = 0; i < BLB_DATA(dn, bn)->num_klpairs(); i++) {
LEAFENTRY curr_le;
uint32_t curr_keylen;
void* curr_key;
......@@ -636,8 +636,8 @@ test_serialize_leaf_with_many_rows(enum ftnode_verify_type bft, bool do_clone) {
if (bn > 0) {
assert(dest_ndd[bn].start >= dest_ndd[bn-1].start + dest_ndd[bn-1].size);
}
assert(BLB_DATA(dn, bn)->dmt_size() > 0);
for (uint32_t i = 0; i < BLB_DATA(dn, bn)->dmt_size(); i++) {
assert(BLB_DATA(dn, bn)->num_klpairs() > 0);
for (uint32_t i = 0; i < BLB_DATA(dn, bn)->num_klpairs(); i++) {
LEAFENTRY curr_le;
uint32_t curr_keylen;
void* curr_key;
......@@ -786,8 +786,8 @@ test_serialize_leaf_with_large_rows(enum ftnode_verify_type bft, bool do_clone)
if (bn > 0) {
assert(dest_ndd[bn].start >= dest_ndd[bn-1].start + dest_ndd[bn-1].size);
}
assert(BLB_DATA(dn, bn)->dmt_size() > 0);
for (uint32_t i = 0; i < BLB_DATA(dn, bn)->dmt_size(); i++) {
assert(BLB_DATA(dn, bn)->num_klpairs() > 0);
for (uint32_t i = 0; i < BLB_DATA(dn, bn)->num_klpairs(); i++) {
LEAFENTRY curr_le;
uint32_t curr_keylen;
void* curr_key;
......@@ -924,7 +924,7 @@ test_serialize_leaf_with_empty_basement_nodes(enum ftnode_verify_type bft, bool
if (bn > 0) {
assert(dest_ndd[bn].start >= dest_ndd[bn-1].start + dest_ndd[bn-1].size);
}
for (uint32_t i = 0; i < BLB_DATA(dn, bn)->dmt_size(); i++) {
for (uint32_t i = 0; i < BLB_DATA(dn, bn)->num_klpairs(); i++) {
LEAFENTRY curr_le;
uint32_t curr_keylen;
void* curr_key;
......@@ -1045,7 +1045,7 @@ test_serialize_leaf_with_multiple_empty_basement_nodes(enum ftnode_verify_type b
if (i > 0) {
assert(dest_ndd[i].start >= dest_ndd[i-1].start + dest_ndd[i-1].size);
}
assert(BLB_DATA(dn, i)->dmt_size() == 0);
assert(BLB_DATA(dn, i)->num_klpairs() == 0);
}
}
toku_ftnode_free(&dn);
......
......@@ -119,7 +119,7 @@ append_leaf(FTNODE leafnode, void *key, size_t keylen, void *val, size_t vallen)
DBT theval; toku_fill_dbt(&theval, val, vallen);
// get an index that we can use to create a new leaf entry
uint32_t idx = BLB_DATA(leafnode, 0)->dmt_size();
uint32_t idx = BLB_DATA(leafnode, 0)->num_klpairs();
MSN msn = next_dummymsn();
......
......@@ -733,7 +733,7 @@ flush_to_leaf(FT_HANDLE t, bool make_leaf_up_to_date, bool use_flush) {
int total_messages = 0;
for (i = 0; i < 8; ++i) {
total_messages += BLB_DATA(child, i)->dmt_size();
total_messages += BLB_DATA(child, i)->num_klpairs();
}
assert(total_messages <= num_parent_messages + num_child_messages);
......@@ -746,7 +746,7 @@ flush_to_leaf(FT_HANDLE t, bool make_leaf_up_to_date, bool use_flush) {
memset(parent_messages_present, 0, sizeof parent_messages_present);
memset(child_messages_present, 0, sizeof child_messages_present);
for (int j = 0; j < 8; ++j) {
uint32_t len = BLB_DATA(child, j)->dmt_size();
uint32_t len = BLB_DATA(child, j)->num_klpairs();
for (uint32_t idx = 0; idx < len; ++idx) {
LEAFENTRY le;
DBT keydbt, valdbt;
......@@ -968,7 +968,7 @@ flush_to_leaf_with_keyrange(FT_HANDLE t, bool make_leaf_up_to_date) {
int total_messages = 0;
for (i = 0; i < 8; ++i) {
total_messages += BLB_DATA(child, i)->dmt_size();
total_messages += BLB_DATA(child, i)->num_klpairs();
}
assert(total_messages <= num_parent_messages + num_child_messages);
......@@ -1146,8 +1146,8 @@ compare_apply_and_flush(FT_HANDLE t, bool make_leaf_up_to_date) {
for (int j = 0; j < 8; ++j) {
bn_data* first = BLB_DATA(child1, j);
bn_data* second = BLB_DATA(child2, j);
uint32_t len = first->dmt_size();
assert(len == second->dmt_size());
uint32_t len = first->num_klpairs();
assert(len == second->num_klpairs());
for (uint32_t idx = 0; idx < len; ++idx) {
LEAFENTRY le1, le2;
DBT key1dbt, val1dbt, key2dbt, val2dbt;
......
......@@ -348,7 +348,7 @@ doit (int state) {
assert(node->height == 0);
assert(!node->dirty);
assert(node->n_children == 1);
assert(BLB_DATA(node, 0)->dmt_size() == 1);
assert(BLB_DATA(node, 0)->num_klpairs() == 1);
toku_unpin_ftnode_off_client_thread(c_ft->ft, node);
toku_pin_ftnode_off_client_thread(
......@@ -364,7 +364,7 @@ doit (int state) {
assert(node->height == 0);
assert(!node->dirty);
assert(node->n_children == 1);
assert(BLB_DATA(node, 0)->dmt_size() == 1);
assert(BLB_DATA(node, 0)->num_klpairs() == 1);
toku_unpin_ftnode_off_client_thread(c_ft->ft, node);
}
else if (state == ft_flush_aflter_merge || state == flt_flush_before_unpin_remove) {
......@@ -381,7 +381,7 @@ doit (int state) {
assert(node->height == 0);
assert(!node->dirty);
assert(node->n_children == 1);
assert(BLB_DATA(node, 0)->dmt_size() == 2);
assert(BLB_DATA(node, 0)->num_klpairs() == 2);
toku_unpin_ftnode_off_client_thread(c_ft->ft, node);
}
else {
......
......@@ -359,7 +359,7 @@ doit (int state) {
assert(node->height == 0);
assert(!node->dirty);
assert(node->n_children == 1);
assert(BLB_DATA(node, 0)->dmt_size() == 2);
assert(BLB_DATA(node, 0)->num_klpairs() == 2);
toku_unpin_ftnode_off_client_thread(c_ft->ft, node);
toku_pin_ftnode_off_client_thread(
......@@ -375,7 +375,7 @@ doit (int state) {
assert(node->height == 0);
assert(!node->dirty);
assert(node->n_children == 1);
assert(BLB_DATA(node, 0)->dmt_size() == 2);
assert(BLB_DATA(node, 0)->num_klpairs() == 2);
toku_unpin_ftnode_off_client_thread(c_ft->ft, node);
......
......@@ -342,7 +342,7 @@ doit (bool after_split) {
assert(node->height == 0);
assert(!node->dirty);
assert(node->n_children == 1);
assert(BLB_DATA(node, 0)->dmt_size() == 1);
assert(BLB_DATA(node, 0)->num_klpairs() == 1);
toku_unpin_ftnode_off_client_thread(c_ft->ft, node);
toku_pin_ftnode_off_client_thread(
......@@ -358,7 +358,7 @@ doit (bool after_split) {
assert(node->height == 0);
assert(!node->dirty);
assert(node->n_children == 1);
assert(BLB_DATA(node, 0)->dmt_size() == 1);
assert(BLB_DATA(node, 0)->num_klpairs() == 1);
toku_unpin_ftnode_off_client_thread(c_ft->ft, node);
}
else {
......@@ -375,7 +375,7 @@ doit (bool after_split) {
assert(node->height == 0);
assert(!node->dirty);
assert(node->n_children == 1);
assert(BLB_DATA(node, 0)->dmt_size() == 2);
assert(BLB_DATA(node, 0)->num_klpairs() == 2);
toku_unpin_ftnode_off_client_thread(c_ft->ft, node);
}
......
......@@ -122,7 +122,7 @@ append_leaf(FTNODE leafnode, void *key, size_t keylen, void *val, size_t vallen)
DBT theval; toku_fill_dbt(&theval, val, vallen);
// get an index that we can use to create a new leaf entry
uint32_t idx = BLB_DATA(leafnode, 0)->dmt_size();
uint32_t idx = BLB_DATA(leafnode, 0)->num_klpairs();
MSN msn = next_dummymsn();
......
......@@ -111,7 +111,7 @@ append_leaf(FTNODE leafnode, void *key, size_t keylen, void *val, size_t vallen)
DBT theval; toku_fill_dbt(&theval, val, vallen);
// get an index that we can use to create a new leaf entry
uint32_t idx = BLB_DATA(leafnode, 0)->dmt_size();
uint32_t idx = BLB_DATA(leafnode, 0)->num_klpairs();
// apply an insert to the leaf node
MSN msn = next_dummymsn();
......
......@@ -112,7 +112,7 @@ append_leaf(FTNODE leafnode, void *key, size_t keylen, void *val, size_t vallen)
DBT theval; toku_fill_dbt(&theval, val, vallen);
// get an index that we can use to create a new leaf entry
uint32_t idx = BLB_DATA(leafnode, 0)->dmt_size();
uint32_t idx = BLB_DATA(leafnode, 0)->num_klpairs();
// apply an insert to the leaf node
MSN msn = next_dummymsn();
......
......@@ -111,7 +111,7 @@ append_leaf(FTNODE leafnode, void *key, size_t keylen, void *val, size_t vallen)
DBT theval; toku_fill_dbt(&theval, val, vallen);
// get an index that we can use to create a new leaf entry
uint32_t idx = BLB_DATA(leafnode, 0)->dmt_size();
uint32_t idx = BLB_DATA(leafnode, 0)->num_klpairs();
// apply an insert to the leaf node
MSN msn = next_dummymsn();
......
......@@ -112,7 +112,7 @@ append_leaf(FTNODE leafnode, void *key, size_t keylen, void *val, size_t vallen)
DBT theval; toku_fill_dbt(&theval, val, vallen);
// get an index that we can use to create a new leaf entry
uint32_t idx = BLB_DATA(leafnode, 0)->dmt_size();
uint32_t idx = BLB_DATA(leafnode, 0)->num_klpairs();
// apply an insert to the leaf node
MSN msn = next_dummymsn();
......
......@@ -114,7 +114,7 @@ append_leaf(FTNODE leafnode, void *key, size_t keylen, void *val, size_t vallen)
toku_fill_dbt(&theval, val, vallen);
// get an index that we can use to create a new leaf entry
uint32_t idx = BLB_DATA(leafnode, 0)->dmt_size();
uint32_t idx = BLB_DATA(leafnode, 0)->num_klpairs();
// apply an insert to the leaf node
MSN msn = next_dummymsn();
......
......@@ -111,7 +111,7 @@ append_leaf(FTNODE leafnode, void *key, size_t keylen, void *val, size_t vallen)
DBT theval; toku_fill_dbt(&theval, val, vallen);
// get an index that we can use to create a new leaf entry
uint32_t idx = BLB_DATA(leafnode, 0)->dmt_size();
uint32_t idx = BLB_DATA(leafnode, 0)->num_klpairs();
// apply an insert to the leaf node
MSN msn = next_dummymsn();
......
......@@ -315,9 +315,9 @@ dump_node (int f, BLOCKNUM blocknum, FT h) {
}
} else {
printf(" n_bytes_in_buffer= %" PRIu64 "", BLB_DATA(n, i)->get_disk_size());
printf(" items_in_buffer=%u\n", BLB_DATA(n, i)->dmt_size());
printf(" items_in_buffer=%u\n", BLB_DATA(n, i)->num_klpairs());
if (dump_data) {
BLB_DATA(n, i)->dmt_iterate<void, print_le>(NULL);
BLB_DATA(n, i)->iterate<void, print_le>(NULL);
}
}
}
......
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