static inline int
si_split(si *index, sdc *c, ssbuf *result,
sinode *parent,
ssiter *i,
uint64_t size_node,
uint64_t size_stream,
uint32_t stream,
uint64_t vlsn)
{
sr *r = &index->r;
uint32_t timestamp = ss_timestamp();
int rc;
sdmergeconf mergeconf = {
.stream = stream,
.size_stream = size_stream,
.size_node = size_node,
.size_page = index->scheme.compaction.node_page_size,
.checksum = index->scheme.compaction.node_page_checksum,
.expire = index->scheme.expire,
.timestamp = timestamp,
.compression = index->scheme.compression,
.compression_if = index->scheme.compression_if,
.direct_io = index->scheme.direct_io,
.direct_io_page_size = index->scheme.direct_io_page_size,
.vlsn = vlsn
};
sinode *n = NULL;
sdmerge merge;
rc = sd_mergeinit(&merge, r, i, &c->build, &c->build_index,
&c->upsert, &mergeconf);
if (ssunlikely(rc == -1))
return -1;
while ((rc = sd_merge(&merge)) > 0)
{
/* create new node */
uint64_t id = sr_seq(index->r.seq, SR_NSNNEXT);
n = si_nodenew(r, id, parent->id);
if (ssunlikely(n == NULL))
goto error;
rc = si_nodecreate(n, r, &index->scheme);
if (ssunlikely(rc == -1))
goto error;
/* write pages */
uint64_t offset;
offset = sd_iosize(&c->io, &n->file);
while ((rc = sd_mergepage(&merge, offset)) == 1) {
rc = sd_writepage(r, &n->file, &c->io, merge.build);
if (ssunlikely(rc == -1))
goto error;
offset = sd_iosize(&c->io, &n->file);
}
if (ssunlikely(rc == -1))
goto error;
offset = sd_iosize(&c->io, &n->file);
rc = sd_mergeend(&merge, offset);
if (ssunlikely(rc == -1))
goto error;
/* write index */
rc = sd_writeindex(r, &n->file, &c->io, &merge.index);
if (ssunlikely(rc == -1))
goto error;
/* mmap mode */
if (index->scheme.mmap) {
rc = si_nodemap(n, r);
if (ssunlikely(rc == -1))
goto error;
}
/* add node to the list */
rc = ss_bufadd(result, index->r.a, &n, sizeof(sinode*));
if (ssunlikely(rc == -1)) {
sr_oom_malfunction(index->r.e);
goto error;
}
n->index = merge.index;
}
if (ssunlikely(rc == -1))
goto error;
return 0;
error:
if (n)
si_nodefree(n, r, 0);
sd_mergefree(&merge);
si_splitfree(result, r);
return -1;
}
static int
si_merge(si *index, sdc *c, sinode *node,
uint64_t vlsn,
ssiter *stream,
uint64_t size_stream,
uint32_t n_stream)
{
sr *r = &index->r;
ssbuf *result = &c->a;
ssiter i;
/* begin compaction.
*
* Split merge stream into a number of
* a new nodes.
*/
int rc;
rc = si_split(index, c, result,
node, stream,
index->scheme.compaction.node_size,
size_stream,
n_stream,
vlsn);
if (ssunlikely(rc == -1))
return -1;
SS_INJECTION(r->i, SS_INJECTION_SI_COMPACTION_0,
si_splitfree(result, r);
sr_malfunction(r->e, "%s", "error injection");
return -1);
/* mask removal of a single node as a
* single node update */
int count = ss_bufused(result) / sizeof(sinode*);
int count_index;
si_lock(index);
count_index = index->n;
si_unlock(index);
sinode *n;
if (ssunlikely(count == 0 && count_index == 1))
{
n = si_bootstrap(index, node->id);
if (ssunlikely(n == NULL))
return -1;
rc = ss_bufadd(result, r->a, &n, sizeof(sinode*));
if (ssunlikely(rc == -1)) {
sr_oom_malfunction(r->e);
si_nodefree(n, r, 1);
return -1;
}
count++;
}
/* commit compaction changes */
si_lock(index);
svindex *j = si_nodeindex(node);
si_plannerremove(&index->p, node);
si_nodesplit(node);
switch (count) {
case 0: /* delete */
si_remove(index, node);
si_redistribute_index(index, r, c, node);
break;
case 1: /* self update */
n = *(sinode**)result->s;
n->i0 = *j;
n->used = j->used;
si_nodelock(n);
si_replace(index, node, n);
si_plannerupdate(&index->p, n);
break;
default: /* split */
rc = si_redistribute(index, r, c, node, result);
if (ssunlikely(rc == -1)) {
si_unlock(index);
si_splitfree(result, r);
return -1;
}
ss_iterinit(ss_bufiterref, &i);
ss_iteropen(ss_bufiterref, &i, result, sizeof(sinode*));
n = ss_iterof(ss_bufiterref, &i);
n->used = n->i0.used;
si_nodelock(n);
si_replace(index, node, n);
si_plannerupdate(&index->p, n);
for (ss_iternext(ss_bufiterref, &i); ss_iterhas(ss_bufiterref, &i);
ss_iternext(ss_bufiterref, &i)) {
n = ss_iterof(ss_bufiterref, &i);
n->used = n->i0.used;
si_nodelock(n);
si_insert(index, n);
si_plannerupdate(&index->p, n);
}
break;
}
sv_indexinit(j);
si_unlock(index);
/* compaction completion */
/* seal nodes */
ss_iterinit(ss_bufiterref, &i);
ss_iteropen(ss_bufiterref, &i, result, sizeof(sinode*));
while (ss_iterhas(ss_bufiterref, &i))
{
n = ss_iterof(ss_bufiterref, &i);
if (index->scheme.sync) {
rc = ss_filesync(&n->file);
if (ssunlikely(rc == -1)) {
sr_malfunction(r->e, "db file '%s' sync error: %s",
ss_pathof(&n->file.path),
strerror(errno));
return -1;
}
}
rc = si_noderename_seal(n, r, &index->scheme);
if (ssunlikely(rc == -1)) {
si_nodefree(node, r, 0);
return -1;
}
SS_INJECTION(r->i, SS_INJECTION_SI_COMPACTION_3,
si_nodefree(node, r, 0);
sr_malfunction(r->e, "%s", "error injection");
return -1);
ss_iternext(ss_bufiterref, &i);
}
SS_INJECTION(r->i, SS_INJECTION_SI_COMPACTION_1,
si_nodefree(node, r, 0);
sr_malfunction(r->e, "%s", "error injection");
return -1);
/* gc node */
uint16_t refs = si_noderefof(node);
if (sslikely(refs == 0)) {
rc = si_nodefree(node, r, 1);
if (ssunlikely(rc == -1))
return -1;
} else {
/* node concurrently being read, schedule for
* delayed removal */
si_nodegc(node, r, &index->scheme);
si_lock(index);
ss_listappend(&index->gc, &node->gc);
index->gc_count++;
si_unlock(index);
}
SS_INJECTION(r->i, SS_INJECTION_SI_COMPACTION_2,
sr_malfunction(r->e, "%s", "error injection");
return -1);
/* complete new nodes */
ss_iterinit(ss_bufiterref, &i);
ss_iteropen(ss_bufiterref, &i, result, sizeof(sinode*));
while (ss_iterhas(ss_bufiterref, &i))
{
n = ss_iterof(ss_bufiterref, &i);
rc = si_noderename_complete(n, r, &index->scheme);
if (ssunlikely(rc == -1))
return -1;
SS_INJECTION(r->i, SS_INJECTION_SI_COMPACTION_4,
sr_malfunction(r->e, "%s", "error injection");
return -1);
ss_iternext(ss_bufiterref, &i);
}
/* unlock */
si_lock(index);
ss_iterinit(ss_bufiterref, &i);
ss_iteropen(ss_bufiterref, &i, result, sizeof(sinode*));
while (ss_iterhas(ss_bufiterref, &i))
{
n = ss_iterof(ss_bufiterref, &i);
si_nodeunlock(n);
ss_iternext(ss_bufiterref, &i);
}
si_unlock(index);
return 0;
}
static inline sibranch*
si_branchcreate(si *index, sdc *c, sinode *parent, svindex *vindex, uint64_t vlsn)
{
sr *r = index->r;
sibranch *branch = NULL;
/* in-memory mode blob */
int rc;
ssblob copy, *blob = NULL;
if (parent->in_memory) {
ss_blobinit(©, r->vfs);
rc = ss_blobensure(©, 10ULL * 1024 * 1024);
if (ssunlikely(rc == -1)) {
sr_oom_malfunction(r->e);
return NULL;
}
blob = ©
}
svmerge vmerge;
sv_mergeinit(&vmerge);
rc = sv_mergeprepare(&vmerge, r, 1);
if (ssunlikely(rc == -1))
return NULL;
svmergesrc *s = sv_mergeadd(&vmerge, NULL);
ss_iterinit(sv_indexiter, &s->src);
ss_iteropen(sv_indexiter, &s->src, r, vindex, SS_GTE, NULL, 0);
ssiter i;
ss_iterinit(sv_mergeiter, &i);
ss_iteropen(sv_mergeiter, &i, r, &vmerge, SS_GTE);
/* merge iter is not used */
sdmergeconf mergeconf = {
.size_stream = UINT32_MAX,
.size_node = UINT64_MAX,
.size_page = index->scheme->node_page_size,
.checksum = index->scheme->node_page_checksum,
.compression_key = index->scheme->compression_key,
.compression = index->scheme->compression_branch,
.compression_if = index->scheme->compression_branch_if,
.vlsn = vlsn,
.vlsn_lru = 0,
.save_delete = 1,
.save_upsert = 1
};
sdmerge merge;
sd_mergeinit(&merge, r, &i, &c->build, &c->upsert, &mergeconf);
while ((rc = sd_merge(&merge)) > 0)
{
assert(branch == NULL);
/* write open seal */
uint64_t seal = parent->file.size;
rc = sd_writeseal(r, &parent->file, blob);
if (ssunlikely(rc == -1))
goto e0;
/* write pages */
uint64_t offset = parent->file.size;
while ((rc = sd_mergepage(&merge, offset)) == 1)
{
rc = sd_writepage(r, &parent->file, blob, merge.build);
if (ssunlikely(rc == -1))
goto e0;
offset = parent->file.size;
}
if (ssunlikely(rc == -1))
goto e0;
sdid id = {
.parent = parent->self.id.id,
.flags = SD_IDBRANCH,
.id = sr_seq(r->seq, SR_NSNNEXT)
};
rc = sd_mergecommit(&merge, &id, parent->file.size);
if (ssunlikely(rc == -1))
goto e0;
/* write index */
rc = sd_writeindex(r, &parent->file, blob, &merge.index);
if (ssunlikely(rc == -1))
goto e0;
if (index->scheme->sync) {
rc = ss_filesync(&parent->file);
if (ssunlikely(rc == -1)) {
sr_malfunction(r->e, "file '%s' sync error: %s",
ss_pathof(&parent->file.path),
strerror(errno));
goto e0;
}
}
SS_INJECTION(r->i, SS_INJECTION_SI_BRANCH_0,
sd_mergefree(&merge);
sr_malfunction(r->e, "%s", "error injection");
return NULL);
/* seal the branch */
rc = sd_seal(r, &parent->file, blob, &merge.index, seal);
if (ssunlikely(rc == -1))
goto e0;
if (index->scheme->sync == 2) {
rc = ss_filesync(&parent->file);
if (ssunlikely(rc == -1)) {
sr_malfunction(r->e, "file '%s' sync error: %s",
ss_pathof(&parent->file.path),
strerror(errno));
goto e0;
}
}
/* create new branch object */
branch = si_branchnew(r);
if (ssunlikely(branch == NULL))
goto e0;
si_branchset(branch, &merge.index);
}
sv_mergefree(&vmerge, r->a);
if (ssunlikely(rc == -1)) {
sr_oom_malfunction(r->e);
goto e0;
}
assert(branch != NULL);
/* in-memory mode support */
if (blob) {
rc = ss_blobfit(blob);
if (ssunlikely(rc == -1)) {
ss_blobfree(blob);
goto e1;
}
branch->copy = copy;
}
/* mmap support */
if (index->scheme->mmap) {
ss_mmapinit(&parent->map_swap);
rc = ss_vfsmmap(r->vfs, &parent->map_swap, parent->file.fd,
parent->file.size, 1);
if (ssunlikely(rc == -1)) {
sr_malfunction(r->e, "db file '%s' mmap error: %s",
ss_pathof(&parent->file.path),
strerror(errno));
goto e1;
}
}
return branch;
e0:
sd_mergefree(&merge);
if (blob)
ss_blobfree(blob);
return NULL;
e1:
si_branchfree(branch, r);
return NULL;
}
int si_branch(si *index, sdc *c, siplan *plan, uint64_t vlsn)
{
sr *r = index->r;
sinode *n = plan->node;
assert(n->flags & SI_LOCK);
si_lock(index);
if (ssunlikely(n->used == 0)) {
si_nodeunlock(n);
si_unlock(index);
return 0;
}
svindex *i;
i = si_noderotate(n);
si_unlock(index);
sibranch *branch = si_branchcreate(index, c, n, i, vlsn);
if (ssunlikely(branch == NULL))
return -1;
/* commit */
si_lock(index);
branch->next = n->branch;
n->branch->link = branch;
n->branch = branch;
n->branch_count++;
uint32_t used = sv_indexused(i);
n->used -= used;
ss_quota(r->quota, SS_QREMOVE, used);
index->size +=
sd_indexsize(branch->index.h) +
sd_indextotal(&branch->index);
svindex swap = *i;
si_nodeunrotate(n);
si_nodeunlock(n);
si_plannerupdate(&index->p, SI_BRANCH|SI_COMPACT, n);
ssmmap swap_map = n->map;
n->map = n->map_swap;
memset(&n->map_swap, 0, sizeof(n->map_swap));
si_unlock(index);
/* gc */
if (index->scheme->mmap) {
int rc = ss_vfsmunmap(r->vfs, &swap_map);
if (ssunlikely(rc == -1)) {
sr_malfunction(r->e, "db file '%s' munmap error: %s",
ss_pathof(&n->file.path),
strerror(errno));
return -1;
}
}
si_nodegc_index(r, &swap);
return 1;
}
int si_compact(si *index, sdc *c, siplan *plan,
uint64_t vlsn,
uint64_t vlsn_lru,
ssiter *vindex,
uint64_t vindex_used)
{
sr *r = index->r;
sinode *node = plan->node;
assert(node->flags & SI_LOCK);
/* prepare for compaction */
int rc;
rc = sd_censure(c, r, node->branch_count);
if (ssunlikely(rc == -1))
return sr_oom_malfunction(r->e);
svmerge merge;
sv_mergeinit(&merge);
rc = sv_mergeprepare(&merge, r, node->branch_count + 1);
if (ssunlikely(rc == -1))
return -1;
/* read node file into memory */
int use_mmap = index->scheme->mmap;
ssmmap *map = &node->map;
ssmmap preload;
if (index->scheme->node_compact_load) {
rc = si_noderead(node, r, &c->c);
if (ssunlikely(rc == -1))
return -1;
preload.p = c->c.s;
preload.size = ss_bufused(&c->c);
map = &preload;
use_mmap = 1;
}
/* include vindex into merge process */
svmergesrc *s;
uint64_t size_stream = 0;
if (vindex) {
s = sv_mergeadd(&merge, vindex);
size_stream = vindex_used;
}
sdcbuf *cbuf = c->head;
sibranch *b = node->branch;
while (b) {
s = sv_mergeadd(&merge, NULL);
/* choose compression type */
int compression;
ssfilterif *compression_if;
if (! si_branchis_root(b)) {
compression = index->scheme->compression_branch;
compression_if = index->scheme->compression_branch_if;
} else {
compression = index->scheme->compression;
compression_if = index->scheme->compression_if;
}
sdreadarg arg = {
.index = &b->index,
.buf = &cbuf->a,
.buf_xf = &cbuf->b,
.buf_read = &c->d,
.index_iter = &cbuf->index_iter,
.page_iter = &cbuf->page_iter,
.use_memory = node->in_memory,
.use_mmap = use_mmap,
.use_mmap_copy = 0,
.use_compression = compression,
.compression_if = compression_if,
.has = 0,
.has_vlsn = 0,
.o = SS_GTE,
.memory = &b->copy,
.mmap = map,
.file = &node->file,
.r = r
};
ss_iterinit(sd_read, &s->src);
int rc = ss_iteropen(sd_read, &s->src, &arg, NULL, 0);
if (ssunlikely(rc == -1))
return sr_oom_malfunction(r->e);
size_stream += sd_indextotal(&b->index);
cbuf = cbuf->next;
b = b->next;
}
ssiter i;
ss_iterinit(sv_mergeiter, &i);
ss_iteropen(sv_mergeiter, &i, r, &merge, SS_GTE);
rc = si_merge(index, c, node, vlsn, vlsn_lru, &i, size_stream);
sv_mergefree(&merge, r->a);
return rc;
}
int si_compact_index(si *index, sdc *c, siplan *plan,
uint64_t vlsn,
uint64_t vlsn_lru)
{
sinode *node = plan->node;
si_lock(index);
if (ssunlikely(node->used == 0)) {
si_nodeunlock(node);
si_unlock(index);
return 0;
}
svindex *vindex;
vindex = si_noderotate(node);
si_unlock(index);
uint64_t size_stream = sv_indexused(vindex);
ssiter i;
ss_iterinit(sv_indexiter, &i);
ss_iteropen(sv_indexiter, &i, index->r, vindex, SS_GTE, NULL, 0);
return si_compact(index, c, plan, vlsn, vlsn_lru, &i, size_stream);
}
