// SPDX-License-Identifier: GPL-3.0-or-later
#define NETDATA_RRD_INTERNALS
#include "rrdengine.h"
#include "pdc.h"
#include "dbengine-compression.h"
rrdeng_stats_t global_io_errors = 0;
rrdeng_stats_t global_fs_errors = 0;
rrdeng_stats_t rrdeng_reserved_file_descriptors = 0;
rrdeng_stats_t global_pg_cache_over_half_dirty_events = 0;
rrdeng_stats_t global_flushing_pressure_page_deletions = 0;
unsigned rrdeng_pages_per_extent = DEFAULT_PAGES_PER_EXTENT;
#if WORKER_UTILIZATION_MAX_JOB_TYPES < (RRDENG_OPCODE_MAX + 2)
#error Please increase WORKER_UTILIZATION_MAX_JOB_TYPES to at least (RRDENG_MAX_OPCODE + 2)
#endif
struct rrdeng_cmd {
struct rrdengine_instance *ctx;
enum rrdeng_opcode opcode;
void *data;
struct completion *completion;
enum storage_priority priority;
dequeue_callback_t dequeue_cb;
struct {
struct rrdeng_cmd *prev;
struct rrdeng_cmd *next;
} queue;
};
static inline struct rrdeng_cmd rrdeng_deq_cmd(bool from_worker);
static inline void worker_dispatch_extent_read(struct rrdeng_cmd cmd, bool from_worker);
static inline void worker_dispatch_query_prep(struct rrdeng_cmd cmd, bool from_worker);
struct rrdeng_main {
uv_thread_t thread;
uv_loop_t loop;
uv_async_t async;
uv_timer_t timer;
uv_timer_t retention_timer;
pid_t tid;
bool shutdown;
size_t flushes_running;
size_t evict_main_running;
size_t evict_open_running;
size_t evict_extent_running;
size_t cleanup_running;
struct {
ARAL *ar;
struct {
SPINLOCK spinlock;
size_t waiting;
struct rrdeng_cmd *waiting_items_by_priority[STORAGE_PRIORITY_INTERNAL_MAX_DONT_USE];
size_t executed_by_priority[STORAGE_PRIORITY_INTERNAL_MAX_DONT_USE];
} unsafe;
} cmd_queue;
struct {
ARAL *ar;
struct {
size_t dispatched;
size_t executing;
} atomics;
} work_cmd;
struct {
ARAL *ar;
} handles;
struct {
ARAL *ar;
} descriptors;
struct {
ARAL *ar;
} xt_io_descr;
} rrdeng_main = {
.thread = 0,
.loop = {},
.async = {},
.timer = {},
.retention_timer = {},
.flushes_running = 0,
.evict_main_running = 0,
.cleanup_running = 0,
.cmd_queue = {
.unsafe = {
.spinlock = NETDATA_SPINLOCK_INITIALIZER,
},
}
};
static void sanity_check(void)
{
BUILD_BUG_ON(WORKER_UTILIZATION_MAX_JOB_TYPES < (RRDENG_OPCODE_MAX + 2));
/* Magic numbers must fit in the super-blocks */
BUILD_BUG_ON(strlen(RRDENG_DF_MAGIC) > RRDENG_MAGIC_SZ);
BUILD_BUG_ON(strlen(RRDENG_JF_MAGIC) > RRDENG_MAGIC_SZ);
/* Version strings must fit in the super-blocks */
BUILD_BUG_ON(strlen(RRDENG_DF_VER) > RRDENG_VER_SZ);
BUILD_BUG_ON(strlen(RRDENG_JF_VER) > RRDENG_VER_SZ);
/* Data file super-block cannot be larger than RRDENG_BLOCK_SIZE */
BUILD_BUG_ON(RRDENG_DF_SB_PADDING_SZ < 0);
BUILD_BUG_ON(sizeof(nd_uuid_t) != UUID_SZ); /* check UUID size */
/* page count must fit in 8 bits */
BUILD_BUG_ON(MAX_PAGES_PER_EXTENT > 255);
}
// ----------------------------------------------------------------------------
// work request cache
typedef void *(*work_cb)(struct rrdengine_instance *ctx, void *data, struct completion *completion, uv_work_t* req);
typedef void (*after_work_cb)(struct rrdengine_instance *ctx, void *data, struct completion *completion, uv_work_t* req, int status);
struct rrdeng_work {
uv_work_t req;
struct rrdengine_instance *ctx;
void *data;
struct completion *completion;
work_cb work_cb;
after_work_cb after_work_cb;
enum rrdeng_opcode opcode;
};
static void work_request_init(void) {
rrdeng_main.work_cmd.ar = aral_create(
"dbengine-work-cmd",
sizeof(struct rrdeng_work),
0,
0,
NULL,
NULL, NULL, false, false
);
telemetry_aral_register(rrdeng_main.work_cmd.ar, "workers");
}
enum LIBUV_WORKERS_STATUS {
LIBUV_WORKERS_RELAXED,
LIBUV_WORKERS_STRESSED,
LIBUV_WORKERS_CRITICAL,
};
static inline enum LIBUV_WORKERS_STATUS work_request_full(void) {
size_t dispatched = __atomic_load_n(&rrdeng_main.work_cmd.atomics.dispatched, __ATOMIC_RELAXED);
if(dispatched >= (size_t)(libuv_worker_threads))
return LIBUV_WORKERS_CRITICAL;
else if(dispatched >= (size_t)(libuv_worker_threads - RESERVED_LIBUV_WORKER_THREADS))
return LIBUV_WORKERS_STRESSED;
return LIBUV_WORKERS_RELAXED;
}
static inline void work_done(struct rrdeng_work *work_request) {
aral_freez(rrdeng_main.work_cmd.ar, work_request);
}
static void work_standard_worker(uv_work_t *req) {
__atomic_add_fetch(&rrdeng_main.work_cmd.atomics.executing, 1, __ATOMIC_RELAXED);
register_libuv_worker_jobs();
worker_is_busy(UV_EVENT_WORKER_INIT);
struct rrdeng_work *work_request = req->data;
work_request->data = work_request->work_cb(work_request->ctx, work_request->data, work_request->completion, req);
worker_is_idle();
if(work_request->opcode == RRDENG_OPCODE_EXTENT_READ || work_request->opcode == RRDENG_OPCODE_QUERY) {
internal_fatal(work_request->after_work_cb != NULL, "DBENGINE: opcodes with a callback should not boosted");
while(1) {
struct rrdeng_cmd cmd = rrdeng_deq_cmd(true);
if (cmd.opcode == RRDENG_OPCODE_NOOP)
break;
worker_is_busy(UV_EVENT_WORKER_INIT);
switch (cmd.opcode) {
case RRDENG_OPCODE_EXTENT_READ:
worker_dispatch_extent_read(cmd, true);
break;
case RRDENG_OPCODE_QUERY:
worker_dispatch_query_prep(cmd, true);
break;
default:
fatal("DBENGINE: Opcode should not be executed synchronously");
break;
}
worker_is_idle();
}
}
__atomic_sub_fetch(&rrdeng_main.work_cmd.atomics.dispatched, 1, __ATOMIC_RELAXED);
__atomic_sub_fetch(&rrdeng_main.work_cmd.atomics.executing, 1, __ATOMIC_RELAXED);
// signal the event loop a worker is available
fatal_assert(0 == uv_async_send(&rrdeng_main.async));
}
static void after_work_standard_callback(uv_work_t* req, int status) {
struct rrdeng_work *work_request = req->data;
worker_is_busy(RRDENG_OPCODE_MAX + work_request->opcode);
if(work_request->after_work_cb)
work_request->after_work_cb(work_request->ctx, work_request->data, work_request->completion, req, status);
work_done(work_request);
worker_is_idle();
}
static bool work_dispatch(struct rrdengine_instance *ctx, void *data, struct completion *completion, enum rrdeng_opcode opcode, work_cb do_work_cb, after_work_cb do_after_work_cb) {
struct rrdeng_work *work_request = NULL;
internal_fatal(rrdeng_main.tid != gettid_cached(), "work_dispatch() can only be run from the event loop thread");
work_request = aral_mallocz(rrdeng_main.work_cmd.ar);
memset(work_request, 0, sizeof(struct rrdeng_work));
work_request->req.data = work_request;
work_request->ctx = ctx;
work_request->data = data;
work_request->completion = completion;
work_request->work_cb = do_work_cb;
work_request->after_work_cb = do_after_work_cb;
work_request->opcode = opcode;
if(uv_queue_work(&rrdeng_main.loop, &work_request->req, work_standard_worker, after_work_standard_callback)) {
internal_fatal(true, "DBENGINE: cannot queue work");
work_done(work_request);
return false;
}
__atomic_add_fetch(&rrdeng_main.work_cmd.atomics.dispatched, 1, __ATOMIC_RELAXED);
return true;
}
// ----------------------------------------------------------------------------
// page descriptor cache
void page_descriptors_init(void) {
rrdeng_main.descriptors.ar = aral_create(
"dbengine-descriptors",
sizeof(struct page_descr_with_data),
0,
0,
NULL,
NULL, NULL, false, false);
telemetry_aral_register(rrdeng_main.xt_io_descr.ar, "descriptors");
}
struct page_descr_with_data *page_descriptor_get(void) {
struct page_descr_with_data *descr = aral_mallocz(rrdeng_main.descriptors.ar);
memset(descr, 0, sizeof(struct page_descr_with_data));
return descr;
}
static inline void page_descriptor_release(struct page_descr_with_data *descr) {
aral_freez(rrdeng_main.descriptors.ar, descr);
}
// ----------------------------------------------------------------------------
// extent io descriptor cache
static void extent_io_descriptor_init(void) {
rrdeng_main.xt_io_descr.ar = aral_create(
"dbengine-extent-io",
sizeof(struct extent_io_descriptor),
0,
0,
NULL,
NULL, NULL, false, false
);
telemetry_aral_register(rrdeng_main.xt_io_descr.ar, "extent io");
}
static struct extent_io_descriptor *extent_io_descriptor_get(void) {
struct extent_io_descriptor *xt_io_descr = aral_mallocz(rrdeng_main.xt_io_descr.ar);
memset(xt_io_descr, 0, sizeof(struct extent_io_descriptor));
return xt_io_descr;
}
static inline void extent_io_descriptor_release(struct extent_io_descriptor *xt_io_descr) {
aral_freez(rrdeng_main.xt_io_descr.ar, xt_io_descr);
}
// ----------------------------------------------------------------------------
// query handle cache
void rrdeng_query_handle_init(void) {
rrdeng_main.handles.ar = aral_create(
"dbengine-query-handles",
sizeof(struct rrdeng_query_handle),
0,
0,
NULL,
NULL, NULL, false, false);
telemetry_aral_register(rrdeng_main.handles.ar, "query handles");
}
struct rrdeng_query_handle *rrdeng_query_handle_get(void) {
struct rrdeng_query_handle *handle = aral_mallocz(rrdeng_main.handles.ar);
memset(handle, 0, sizeof(struct rrdeng_query_handle));
return handle;
}
void rrdeng_query_handle_release(struct rrdeng_query_handle *handle) {
aral_freez(rrdeng_main.handles.ar, handle);
}
// ----------------------------------------------------------------------------
// WAL cache
static struct {
struct {
SPINLOCK spinlock;
WAL *available_items;
size_t available;
} protected;
struct {
size_t allocated;
} atomics;
} wal_globals = {
.protected = {
.spinlock = NETDATA_SPINLOCK_INITIALIZER,
.available_items = NULL,
.available = 0,
},
.atomics = {
.allocated = 0,
},
};
static void wal_cleanup1(void) {
WAL *wal = NULL;
if(!spinlock_trylock(&wal_globals.protected.spinlock))
return;
if(wal_globals.protected.available_items && wal_globals.protected.available > storage_tiers) {
wal = wal_globals.protected.available_items;
DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(wal_globals.protected.available_items, wal, cache.prev, cache.next);
wal_globals.protected.available--;
}
spinlock_unlock(&wal_globals.protected.spinlock);
if(wal) {
posix_memfree(wal->buf);
freez(wal);
__atomic_sub_fetch(&wal_globals.atomics.allocated, 1, __ATOMIC_RELAXED);
}
}
WAL *wal_get(struct rrdengine_instance *ctx, unsigned size) {
if(!size || size > RRDENG_BLOCK_SIZE)
fatal("DBENGINE: invalid WAL size requested");
WAL *wal = NULL;
spinlock_lock(&wal_globals.protected.spinlock);
if(likely(wal_globals.protected.available_items)) {
wal = wal_globals.protected.available_items;
DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(wal_globals.protected.available_items, wal, cache.prev, cache.next);
wal_globals.protected.available--;
}
uint64_t transaction_id = __atomic_fetch_add(&ctx->atomic.transaction_id, 1, __ATOMIC_RELAXED);
spinlock_unlock(&wal_globals.protected.spinlock);
if(unlikely(!wal)) {
wal = mallocz(sizeof(WAL));
wal->buf_size = RRDENG_BLOCK_SIZE;
int ret = posix_memalign((void *)&wal->buf, RRDFILE_ALIGNMENT, wal->buf_size);
if (unlikely(ret))
fatal("DBENGINE: posix_memalign:%s", strerror(ret));
__atomic_add_fetch(&wal_globals.atomics.allocated, 1, __ATOMIC_RELAXED);
}
// these need to survive
unsigned buf_size = wal->buf_size;
void *buf = wal->buf;
memset(wal, 0, sizeof(WAL));
// put them back
wal->buf_size = buf_size;
wal->buf = buf;
memset(wal->buf, 0, wal->buf_size);
wal->transaction_id = transaction_id;
wal->size = size;
return wal;
}
void wal_release(WAL *wal) {
if(unlikely(!wal)) return;
spinlock_lock(&wal_globals.protected.spinlock);
DOUBLE_LINKED_LIST_APPEND_ITEM_UNSAFE(wal_globals.protected.available_items, wal, cache.prev, cache.next);
wal_globals.protected.available++;
spinlock_unlock(&wal_globals.protected.spinlock);
}
// ----------------------------------------------------------------------------
// command queue cache
static void rrdeng_cmd_queue_init(void) {
rrdeng_main.cmd_queue.ar = aral_create("dbengine-opcodes",
sizeof(struct rrdeng_cmd),
0,
0,
NULL,
NULL, NULL, false, false);
telemetry_aral_register(rrdeng_main.cmd_queue.ar, "opcodes");
}
static inline STORAGE_PRIORITY rrdeng_enq_cmd_map_opcode_to_priority(enum rrdeng_opcode opcode, STORAGE_PRIORITY priority) {
if(unlikely(priority >= STORAGE_PRIORITY_INTERNAL_MAX_DONT_USE))
priority = STORAGE_PRIORITY_BEST_EFFORT;
switch(opcode) {
case RRDENG_OPCODE_QUERY:
priority = STORAGE_PRIORITY_INTERNAL_QUERY_PREP;
break;
default:
break;
}
return priority;
}
void rrdeng_enqueue_epdl_cmd(struct rrdeng_cmd *cmd) {
epdl_cmd_queued(cmd->data, cmd);
}
void rrdeng_dequeue_epdl_cmd(struct rrdeng_cmd *cmd) {
epdl_cmd_dequeued(cmd->data);
}
void rrdeng_req_cmd(requeue_callback_t get_cmd_cb, void *data, STORAGE_PRIORITY priority) {
spinlock_lock(&rrdeng_main.cmd_queue.unsafe.spinlock);
struct rrdeng_cmd *cmd = get_cmd_cb(data);
if(cmd) {
priority = rrdeng_enq_cmd_map_opcode_to_priority(cmd->opcode, priority);
if (cmd->priority > priority) {
DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(rrdeng_main.cmd_queue.unsafe.waiting_items_by_priority[cmd->priority], cmd, queue.prev, queue.next);
DOUBLE_LINKED_LIST_APPEND_ITEM_UNSAFE(rrdeng_main.cmd_queue.unsafe.waiting_items_by_priority[priority], cmd, queue.prev, queue.next);
cmd->priority = priority;
}
}
spinlock_unlock(&rrdeng_main.cmd_queue.unsafe.spinlock);
}
void rrdeng_enq_cmd(struct rrdengine_instance *ctx, enum rrdeng_opcode opcode, void *data, struct completion *completion,
enum storage_priority priority, enqueue_callback_t enqueue_cb, dequeue_callback_t dequeue_cb) {
priority = rrdeng_enq_cmd_map_opcode_to_priority(opcode, priority);
struct rrdeng_cmd *cmd = aral_mallocz(rrdeng_main.cmd_queue.ar);
memset(cmd, 0, sizeof(struct rrdeng_cmd));
cmd->ctx = ctx;
cmd->opcode = opcode;
cmd->data = data;
cmd->completion = completion;
cmd->priority = priority;
cmd->dequeue_cb = dequeue_cb;
spinlock_lock(&rrdeng_main.cmd_queue.unsafe.spinlock);
DOUBLE_LINKED_LIST_APPEND_ITEM_UNSAFE(rrdeng_main.cmd_queue.unsafe.waiting_items_by_priority[priority], cmd, queue.prev, queue.next);
rrdeng_main.cmd_queue.unsafe.waiting++;
if(enqueue_cb)
enqueue_cb(cmd);
spinlock_unlock(&rrdeng_main.cmd_queue.unsafe.spinlock);
fatal_assert(0 == uv_async_send(&rrdeng_main.async));
}
static inline bool rrdeng_cmd_has_waiting_opcodes_in_lower_priorities(STORAGE_PRIORITY priority, STORAGE_PRIORITY max_priority) {
for(; priority <= max_priority ; priority++)
if(rrdeng_main.cmd_queue.unsafe.waiting_items_by_priority[priority])
return true;
return false;
}
#define opcode_empty (struct rrdeng_cmd) { \
.ctx = NULL, \
.opcode = RRDENG_OPCODE_NOOP, \
.priority = STORAGE_PRIORITY_BEST_EFFORT, \
.completion = NULL, \
.data = NULL, \
}
static inline struct rrdeng_cmd rrdeng_deq_cmd(bool from_worker) {
struct rrdeng_cmd *cmd = NULL;
enum LIBUV_WORKERS_STATUS status = work_request_full();
STORAGE_PRIORITY min_priority, max_priority;
min_priority = STORAGE_PRIORITY_INTERNAL_DBENGINE;
max_priority = (status != LIBUV_WORKERS_RELAXED) ? STORAGE_PRIORITY_INTERNAL_DBENGINE : STORAGE_PRIORITY_INTERNAL_MAX_DONT_USE - 1;
if(from_worker) {
if(status == LIBUV_WORKERS_CRITICAL)
return opcode_empty;
min_priority = STORAGE_PRIORITY_INTERNAL_QUERY_PREP;
max_priority = STORAGE_PRIORITY_BEST_EFFORT;
}
// find an opcode to execute from the queue
spinlock_lock(&rrdeng_main.cmd_queue.unsafe.spinlock);
for(STORAGE_PRIORITY priority = min_priority; priority <= max_priority ; priority++) {
cmd = rrdeng_main.cmd_queue.unsafe.waiting_items_by_priority[priority];
if(cmd) {
// avoid starvation of lower priorities
if(unlikely(priority >= STORAGE_PRIORITY_HIGH &&
priority < STORAGE_PRIORITY_BEST_EFFORT &&
++rrdeng_main.cmd_queue.unsafe.executed_by_priority[priority] % 50 == 0 &&
rrdeng_cmd_has_waiting_opcodes_in_lower_priorities(priority + 1, max_priority))) {
// let the others run 2% of the requests
cmd = NULL;
continue;
}
// remove it from the queue
DOUBLE_LINKED_LIST_REMOVE_ITEM_UNSAFE(rrdeng_main.cmd_queue.unsafe.waiting_items_by_priority[priority], cmd, queue.prev, queue.next);
rrdeng_main.cmd_queue.unsafe.waiting--;
break;
}
}
if(cmd && cmd->dequeue_cb) {
cmd->dequeue_cb(cmd);
cmd->dequeue_cb = NULL;
}
spinlock_unlock(&rrdeng_main.cmd_queue.unsafe.spinlock);
struct rrdeng_cmd ret;
if(cmd) {
// copy it, to return it
ret = *cmd;
aral_freez(rrdeng_main.cmd_queue.ar, cmd);
}
else
ret = opcode_empty;
return ret;
}
// ----------------------------------------------------------------------------
void *dbengine_extent_alloc(size_t size) {
void *extent = mallocz(size);
return extent;
}
void dbengine_extent_free(void *extent, size_t size __maybe_unused) {
freez(extent);
}
static void journalfile_extent_build(struct rrdengine_instance *ctx, struct extent_io_descriptor *xt_io_descr) {
unsigned count, payload_length, descr_size, size_bytes;
void *buf;
/* persistent structures */
struct rrdeng_df_extent_header *df_header;
struct rrdeng_jf_transaction_header *jf_header;
struct rrdeng_jf_store_data *jf_metric_data;
struct rrdeng_jf_transaction_trailer *jf_trailer;
uLong crc;
df_header = xt_io_descr->buf;
count = df_header->number_of_pages;
descr_size = sizeof(*jf_metric_data->descr) * count;
payload_length = sizeof(*jf_metric_data) + descr_size;
size_bytes = sizeof(*jf_header) + payload_length + sizeof(*jf_trailer);
xt_io_descr->wal = wal_get(ctx, size_bytes);
buf = xt_io_descr->wal->buf;
jf_header = buf;
jf_header->type = STORE_DATA;
jf_header->reserved = 0;
jf_header->id = xt_io_descr->wal->transaction_id;
jf_header->payload_length = payload_length;
jf_metric_data = buf + sizeof(*jf_header);
jf_metric_data->extent_offset = xt_io_descr->pos;
jf_metric_data->extent_size = xt_io_descr->bytes;
jf_metric_data->number_of_pages = count;
memcpy(jf_metric_data->descr, df_header->descr, descr_size);
jf_trailer = buf + sizeof(*jf_header) + payload_length;
crc = crc32(0L, Z_NULL, 0);
crc = crc32(crc, buf, sizeof(*jf_header) + payload_length);
crc32set(jf_trailer->checksum, crc);
}
static void after_extent_flushed_to_open(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* req __maybe_unused, int status __maybe_unused) {
if(completion)
completion_mark_complete(completion);
if(ctx_is_available_for_queries(ctx))
rrdeng_enq_cmd(ctx, RRDENG_OPCODE_DATABASE_ROTATE, NULL, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL);
}
static void *extent_flushed_to_open_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *uv_work_req __maybe_unused) {
worker_is_busy(UV_EVENT_DBENGINE_FLUSHED_TO_OPEN);
uv_fs_t *uv_fs_request = data;
struct extent_io_descriptor *xt_io_descr = uv_fs_request->data;
struct page_descr_with_data *descr;
struct rrdengine_datafile *datafile;
unsigned i;
datafile = xt_io_descr->datafile;
bool still_running = ctx_is_available_for_queries(ctx);
for (i = 0 ; i < xt_io_descr->descr_count ; ++i) {
descr = xt_io_descr->descr_array[i];
if (likely(still_running))
pgc_open_add_hot_page(
(Word_t)ctx, descr->metric_id,
(time_t) (descr->start_time_ut / USEC_PER_SEC),
(time_t) (descr->end_time_ut / USEC_PER_SEC),
descr->update_every_s,
datafile,
xt_io_descr->pos, xt_io_descr->bytes, descr->page_length);
page_descriptor_release(descr);
}
uv_fs_req_cleanup(uv_fs_request);
posix_memfree(xt_io_descr->buf);
extent_io_descriptor_release(xt_io_descr);
spinlock_lock(&datafile->writers.spinlock);
datafile->writers.flushed_to_open_running--;
spinlock_unlock(&datafile->writers.spinlock);
if(datafile->fileno != ctx_last_fileno_get(ctx) && still_running)
// we just finished a flushing on a datafile that is not the active one
rrdeng_enq_cmd(ctx, RRDENG_OPCODE_JOURNAL_INDEX, datafile, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL);
return data;
}
// Main event loop callback
static void after_extent_write_datafile_io(uv_fs_t *uv_fs_request) {
worker_is_busy(RRDENG_OPCODE_MAX + RRDENG_OPCODE_EXTENT_WRITE);
struct extent_io_descriptor *xt_io_descr = uv_fs_request->data;
struct rrdengine_datafile *datafile = xt_io_descr->datafile;
struct rrdengine_instance *ctx = datafile->ctx;
if (uv_fs_request->result < 0) {
ctx_io_error(ctx);
netdata_log_error("DBENGINE: %s: uv_fs_write(): %s", __func__, uv_strerror((int)uv_fs_request->result));
}
journalfile_v1_extent_write(ctx, xt_io_descr->datafile, xt_io_descr->wal, &rrdeng_main.loop);
spinlock_lock(&datafile->writers.spinlock);
datafile->writers.running--;
datafile->writers.flushed_to_open_running++;
spinlock_unlock(&datafile->writers.spinlock);
rrdeng_enq_cmd(xt_io_descr->ctx,
RRDENG_OPCODE_FLUSHED_TO_OPEN,
uv_fs_request,
xt_io_descr->completion,
STORAGE_PRIORITY_INTERNAL_DBENGINE,
NULL,
NULL);
worker_is_idle();
}
static bool datafile_is_full(struct rrdengine_instance *ctx, struct rrdengine_datafile *datafile) {
bool ret = false;
spinlock_lock(&datafile->writers.spinlock);
if(ctx_is_available_for_queries(ctx) && datafile->pos > rrdeng_target_data_file_size(ctx))
ret = true;
spinlock_unlock(&datafile->writers.spinlock);
return ret;
}
static struct rrdengine_datafile *get_datafile_to_write_extent(struct rrdengine_instance *ctx) {
struct rrdengine_datafile *datafile;
// get the latest datafile
uv_rwlock_rdlock(&ctx->datafiles.rwlock);
datafile = ctx->datafiles.first->prev;
// become a writer on this datafile, to prevent it from vanishing
spinlock_lock(&datafile->writers.spinlock);
datafile->writers.running++;
spinlock_unlock(&datafile->writers.spinlock);
uv_rwlock_rdunlock(&ctx->datafiles.rwlock);
if(datafile_is_full(ctx, datafile)) {
// remember the datafile we have become writers to
struct rrdengine_datafile *old_datafile = datafile;
// only 1 datafile creation at a time
static netdata_mutex_t mutex = NETDATA_MUTEX_INITIALIZER;
netdata_mutex_lock(&mutex);
// take the latest datafile again - without this, multiple threads may create multiple files
uv_rwlock_rdlock(&ctx->datafiles.rwlock);
datafile = ctx->datafiles.first->prev;
uv_rwlock_rdunlock(&ctx->datafiles.rwlock);
if(datafile_is_full(ctx, datafile) && create_new_datafile_pair(ctx, true) == 0)
rrdeng_enq_cmd(ctx, RRDENG_OPCODE_JOURNAL_INDEX, datafile, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL,
NULL);
netdata_mutex_unlock(&mutex);
// get the new latest datafile again, like above
uv_rwlock_rdlock(&ctx->datafiles.rwlock);
datafile = ctx->datafiles.first->prev;
// become a writer on this datafile, to prevent it from vanishing
spinlock_lock(&datafile->writers.spinlock);
datafile->writers.running++;
spinlock_unlock(&datafile->writers.spinlock);
uv_rwlock_rdunlock(&ctx->datafiles.rwlock);
// release the writers on the old datafile
spinlock_lock(&old_datafile->writers.spinlock);
old_datafile->writers.running--;
spinlock_unlock(&old_datafile->writers.spinlock);
}
return datafile;
}
/*
* Take a page list in a judy array and write them
*/
static struct extent_io_descriptor *datafile_extent_build(struct rrdengine_instance *ctx, struct page_descr_with_data *base, struct completion *completion) {
int ret;
unsigned i, count, size_bytes, pos, real_io_size;
uint32_t uncompressed_payload_length, max_compressed_size, payload_offset;
struct page_descr_with_data *descr, *eligible_pages[MAX_PAGES_PER_EXTENT];
struct extent_io_descriptor *xt_io_descr;
Word_t Index;
uint8_t compression_algorithm = ctx->config.global_compress_alg;
struct rrdengine_datafile *datafile;
/* persistent structures */
struct rrdeng_df_extent_header *header;
struct rrdeng_df_extent_trailer *trailer;
uLong crc;
for(descr = base, Index = 0, count = 0, uncompressed_payload_length = 0;
descr && count != rrdeng_pages_per_extent;
descr = descr->link.next, Index++) {
uncompressed_payload_length += descr->page_length;
eligible_pages[count++] = descr;
}
if (!count) {
if (completion)
completion_mark_complete(completion);
__atomic_sub_fetch(&ctx->atomic.extents_currently_being_flushed, 1, __ATOMIC_RELAXED);
return NULL;
}
xt_io_descr = extent_io_descriptor_get();
xt_io_descr->ctx = ctx;
payload_offset = sizeof(*header) + count * sizeof(header->descr[0]);
max_compressed_size = dbengine_max_compressed_size(uncompressed_payload_length, compression_algorithm);
size_bytes = payload_offset + MAX(uncompressed_payload_length, max_compressed_size) + sizeof(*trailer);
ret = posix_memalign((void *)&xt_io_descr->buf, RRDFILE_ALIGNMENT, ALIGN_BYTES_CEILING(size_bytes));
if (unlikely(ret)) {
fatal("DBENGINE: posix_memalign:%s", strerror(ret));
/* freez(xt_io_descr);*/
}
memset(xt_io_descr->buf, 0, ALIGN_BYTES_CEILING(size_bytes));
(void) memcpy(xt_io_descr->descr_array, eligible_pages, sizeof(struct page_descr_with_data *) * count);
xt_io_descr->descr_count = count;
pos = 0;
header = xt_io_descr->buf;
header->number_of_pages = count;
pos += sizeof(*header);
for (i = 0 ; i < count ; ++i) {
descr = xt_io_descr->descr_array[i];
header->descr[i].type = descr->type;
uuid_copy(*(nd_uuid_t *)header->descr[i].uuid, *descr->id);
header->descr[i].page_length = descr->page_length;
header->descr[i].start_time_ut = descr->start_time_ut;
switch (descr->type) {
case RRDENG_PAGE_TYPE_ARRAY_32BIT:
case RRDENG_PAGE_TYPE_ARRAY_TIER1:
header->descr[i].end_time_ut = descr->end_time_ut;
break;
case RRDENG_PAGE_TYPE_GORILLA_32BIT:
header->descr[i].gorilla.delta_time_s = (uint32_t) ((descr->end_time_ut - descr->start_time_ut) / USEC_PER_SEC);
header->descr[i].gorilla.entries = pgd_slots_used(descr->pgd);
break;
default:
fatal("Unknown page type: %uc", descr->type);
}
pos += sizeof(header->descr[i]);
}
// build the extent payload
for (i = 0 ; i < count ; ++i) {
descr = xt_io_descr->descr_array[i];
pgd_copy_to_extent(descr->pgd, xt_io_descr->buf + pos, descr->page_length);
pos += descr->page_length;
}
// compress the payload
size_t compressed_size =
(int)dbengine_compress(xt_io_descr->buf + payload_offset,
uncompressed_payload_length,
compression_algorithm);
internal_fatal(compressed_size > max_compressed_size, "DBENGINE: compression returned more data than the max allowed");
internal_fatal(compressed_size > uncompressed_payload_length, "DBENGINE: compression returned more data than the uncompressed extent");
if(compressed_size) {
header->compression_algorithm = compression_algorithm;
header->payload_length = compressed_size;
}
else {
// compression failed, or generated bigger pages
// so it didn't touch our uncompressed buffer
header->compression_algorithm = RRDENG_COMPRESSION_NONE;
header->payload_length = compressed_size = uncompressed_payload_length;
}
// set the correct size
size_bytes = payload_offset + compressed_size + sizeof(*trailer);
if(compression_algorithm != RRDENG_COMPRESSION_NONE) {
__atomic_add_fetch(&ctx->stats.before_compress_bytes, uncompressed_payload_length, __ATOMIC_RELAXED);
__atomic_add_fetch(&ctx->stats.after_compress_bytes, compressed_size, __ATOMIC_RELAXED);
}
real_io_size = ALIGN_BYTES_CEILING(size_bytes);
datafile = get_datafile_to_write_extent(ctx);
spinlock_lock(&datafile->writers.spinlock);
xt_io_descr->datafile = datafile;
xt_io_descr->pos = datafile->pos;
datafile->pos += real_io_size;
spinlock_unlock(&datafile->writers.spinlock);
xt_io_descr->bytes = size_bytes;
xt_io_descr->uv_fs_request.data = xt_io_descr;
xt_io_descr->completion = completion;
trailer = xt_io_descr->buf + size_bytes - sizeof(*trailer);
crc = crc32(0L, Z_NULL, 0);
crc = crc32(crc, xt_io_descr->buf, size_bytes - sizeof(*trailer));
crc32set(trailer->checksum, crc);
xt_io_descr->iov = uv_buf_init((void *)xt_io_descr->buf, real_io_size);
journalfile_extent_build(ctx, xt_io_descr);
ctx_last_flush_fileno_set(ctx, datafile->fileno);
ctx_current_disk_space_increase(ctx, real_io_size);
ctx_io_write_op_bytes(ctx, real_io_size);
return xt_io_descr;
}
static void after_extent_write(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* uv_work_req __maybe_unused, int status __maybe_unused) {
struct extent_io_descriptor *xt_io_descr = data;
if(xt_io_descr) {
int ret = uv_fs_write(&rrdeng_main.loop,
&xt_io_descr->uv_fs_request,
xt_io_descr->datafile->file,
&xt_io_descr->iov,
1,
(int64_t) xt_io_descr->pos,
after_extent_write_datafile_io);
fatal_assert(-1 != ret);
}
}
static void *extent_write_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *uv_work_req __maybe_unused) {
worker_is_busy(UV_EVENT_DBENGINE_EXTENT_WRITE);
struct page_descr_with_data *base = data;
struct extent_io_descriptor *xt_io_descr = datafile_extent_build(ctx, base, completion);
return xt_io_descr;
}
static void after_database_rotate(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* req __maybe_unused, int status __maybe_unused) {
__atomic_store_n(&ctx->atomic.now_deleting_files, false, __ATOMIC_RELAXED);
}
struct uuid_first_time_s {
nd_uuid_t *uuid;
time_t first_time_s;
METRIC *metric;
size_t pages_found;
size_t df_matched;
size_t df_index_oldest;
};
struct rrdengine_datafile *datafile_release_and_acquire_next_for_retention(struct rrdengine_instance *ctx, struct rrdengine_datafile *datafile) {
uv_rwlock_rdlock(&ctx->datafiles.rwlock);
struct rrdengine_datafile *next_datafile = datafile->next;
while(next_datafile && !datafile_acquire(next_datafile, DATAFILE_ACQUIRE_RETENTION))
next_datafile = next_datafile->next;
uv_rwlock_rdunlock(&ctx->datafiles.rwlock);
datafile_release(datafile, DATAFILE_ACQUIRE_RETENTION);
return next_datafile;
}
time_t find_uuid_first_time(
struct rrdengine_instance *ctx,
struct rrdengine_datafile *datafile,
struct uuid_first_time_s *uuid_first_entry_list,
size_t count)
{
time_t global_first_time_s = LONG_MAX;
// acquire the datafile to work with it
uv_rwlock_rdlock(&ctx->datafiles.rwlock);
while(datafile && !datafile_acquire(datafile, DATAFILE_ACQUIRE_RETENTION))
datafile = datafile->next;
uv_rwlock_rdunlock(&ctx->datafiles.rwlock);
if (unlikely(!datafile))
return global_first_time_s;
unsigned journalfile_count = 0;
size_t binary_match = 0;
size_t not_matching_bsearches = 0;
while (datafile) {
struct journal_v2_header *j2_header = journalfile_v2_data_acquire(datafile->journalfile, NULL, 0, 0);
if (!j2_header) {
datafile = datafile_release_and_acquire_next_for_retention(ctx, datafile);
continue;
}
time_t journal_start_time_s = (time_t) (j2_header->start_time_ut / USEC_PER_SEC);
if(journal_start_time_s < global_first_time_s)
global_first_time_s = journal_start_time_s;
struct journal_metric_list *uuid_list = (struct journal_metric_list *)((uint8_t *) j2_header + j2_header->metric_offset);
struct uuid_first_time_s *uuid_original_entry;
size_t journal_metric_count = j2_header->metric_count;
for (size_t index = 0; index < count; ++index) {
uuid_original_entry = &uuid_first_entry_list[index];
// Check here if we should skip this
if (uuid_original_entry->df_matched > 3 || uuid_original_entry->pages_found > 5)
continue;
struct journal_metric_list *live_entry =
bsearch(uuid_original_entry->uuid,uuid_list,journal_metric_count,
sizeof(*uuid_list), journal_metric_uuid_compare);
if (!live_entry) {
// Not found in this journal
not_matching_bsearches++;
continue;
}
uuid_original_entry->pages_found += live_entry->entries;
uuid_original_entry->df_matched++;
time_t old_first_time_s = uuid_original_entry->first_time_s;
// Calculate first / last for this match
time_t first_time_s = live_entry->delta_start_s + journal_start_time_s;
uuid_original_entry->first_time_s = MIN(uuid_original_entry->first_time_s, first_time_s);
if (uuid_original_entry->first_time_s != old_first_time_s)
uuid_original_entry->df_index_oldest = uuid_original_entry->df_matched;
binary_match++;
}
journalfile_count++;
journalfile_v2_data_release(datafile->journalfile);
datafile = datafile_release_and_acquire_next_for_retention(ctx, datafile);
}
// Let's scan the open cache for almost exact match
size_t open_cache_count = 0;
size_t df_index[10] = { 0 };
size_t without_metric = 0;
size_t open_cache_gave_first_time_s = 0;
size_t metric_count = 0;
size_t without_retention = 0;
size_t not_needed_bsearches = 0;
for (size_t index = 0; index < count; ++index) {
struct uuid_first_time_s *uuid_first_t_entry = &uuid_first_entry_list[index];
metric_count++;
size_t idx = uuid_first_t_entry->df_index_oldest;
if(idx >= 10)
idx = 9;
df_index[idx]++;
not_needed_bsearches += uuid_first_t_entry->df_matched - uuid_first_t_entry->df_index_oldest;
if (unlikely(!uuid_first_t_entry->metric)) {
without_metric++;
continue;
}
PGC_PAGE *page = pgc_page_get_and_acquire(
open_cache, (Word_t)ctx,
(Word_t)uuid_first_t_entry->metric, 0,
PGC_SEARCH_FIRST);
if (page) {
time_t old_first_time_s = uuid_first_t_entry->first_time_s;
time_t first_time_s = pgc_page_start_time_s(page);
uuid_first_t_entry->first_time_s = MIN(uuid_first_t_entry->first_time_s, first_time_s);
pgc_page_release(open_cache, page);
open_cache_count++;
if(uuid_first_t_entry->first_time_s != old_first_time_s) {
open_cache_gave_first_time_s++;
}
}
else {
if(!uuid_first_t_entry->df_index_oldest)
without_retention++;
}
}
internal_error(true,
"DBENGINE: analyzed the retention of %zu rotated metrics of tier %d, "
"did %zu jv2 matching binary searches (%zu not matching, %zu overflown) in %u journal files, "
"%zu metrics with entries in open cache, "
"metrics first time found per datafile index ([not in jv2]:%zu, [1]:%zu, [2]:%zu, [3]:%zu, [4]:%zu, [5]:%zu, [6]:%zu, [7]:%zu, [8]:%zu, [bigger]: %zu), "
"open cache found first time %zu, "
"metrics without any remaining retention %zu, "
"metrics not in MRG %zu",
metric_count,
ctx->config.tier,
binary_match,
not_matching_bsearches,
not_needed_bsearches,
journalfile_count,
open_cache_count,
df_index[0], df_index[1], df_index[2], df_index[3], df_index[4], df_index[5], df_index[6], df_index[7], df_index[8], df_index[9],
open_cache_gave_first_time_s,
without_retention,
without_metric
);
return global_first_time_s;
}
static void update_metrics_first_time_s(struct rrdengine_instance *ctx, struct rrdengine_datafile *datafile_to_delete, struct rrdengine_datafile *first_datafile_remaining, bool worker) {
time_t global_first_time_s = LONG_MAX;
if(worker)
worker_is_busy(UV_EVENT_DBENGINE_FIND_ROTATED_METRICS);
struct rrdengine_journalfile *journalfile = datafile_to_delete->journalfile;
struct journal_v2_header *j2_header = journalfile_v2_data_acquire(journalfile, NULL, 0, 0);
if (unlikely(!j2_header)) {
if (worker)
worker_is_idle();
return;
}
__atomic_add_fetch(&rrdeng_cache_efficiency_stats.metrics_retention_started, 1, __ATOMIC_RELAXED);
struct journal_metric_list *uuid_list = (struct journal_metric_list *)((uint8_t *) j2_header + j2_header->metric_offset);
size_t count = j2_header->metric_count;
struct uuid_first_time_s *uuid_first_t_entry;
struct uuid_first_time_s *uuid_first_entry_list = callocz(count, sizeof(struct uuid_first_time_s));
size_t added = 0;
for (size_t index = 0; index < count; ++index) {
METRIC *metric = mrg_metric_get_and_acquire(main_mrg, &uuid_list[index].uuid, (Word_t) ctx);
if (!metric)
continue;
uuid_first_entry_list[added].metric = metric;
uuid_first_entry_list[added].first_time_s = LONG_MAX;
uuid_first_entry_list[added].df_matched = 0;
uuid_first_entry_list[added].df_index_oldest = 0;
uuid_first_entry_list[added].uuid = mrg_metric_uuid(main_mrg, metric);
added++;
}
netdata_log_info("DBENGINE: recalculating tier %d retention for %zu metrics starting with datafile %u",
ctx->config.tier, count, first_datafile_remaining->fileno);
journalfile_v2_data_release(journalfile);
// Update the first time / last time for all metrics we plan to delete
if(worker)
worker_is_busy(UV_EVENT_DBENGINE_FIND_REMAINING_RETENTION);
global_first_time_s = find_uuid_first_time(ctx, first_datafile_remaining, uuid_first_entry_list, added);
if(worker)
worker_is_busy(UV_EVENT_DBENGINE_POPULATE_MRG);
netdata_log_info("DBENGINE: updating tier %d metrics registry retention for %zu metrics",
ctx->config.tier, added);
size_t deleted_metrics = 0, zero_retention_referenced = 0, zero_disk_retention = 0, zero_disk_but_live = 0;
for (size_t index = 0; index < added; ++index) {
uuid_first_t_entry = &uuid_first_entry_list[index];
if (likely(uuid_first_t_entry->first_time_s != LONG_MAX)) {
time_t old_first_time_s = mrg_metric_get_first_time_s(main_mrg, uuid_first_t_entry->metric);
bool changed = mrg_metric_set_first_time_s_if_bigger(main_mrg, uuid_first_t_entry->metric, uuid_first_t_entry->first_time_s);
if (changed) {
uint32_t update_every_s = mrg_metric_get_update_every_s(main_mrg, uuid_first_t_entry->metric);
if (update_every_s && old_first_time_s && uuid_first_t_entry->first_time_s > old_first_time_s) {
uint64_t remove_samples = (uuid_first_t_entry->first_time_s - old_first_time_s) / update_every_s;
__atomic_sub_fetch(&ctx->atomic.samples, remove_samples, __ATOMIC_RELAXED);
}
}
mrg_metric_release(main_mrg, uuid_first_t_entry->metric);
}
else {
zero_disk_retention++;
// there is no retention for this metric
bool has_retention = mrg_metric_zero_disk_retention(main_mrg, uuid_first_t_entry->metric);
if (!has_retention) {
time_t first_time_s = mrg_metric_get_first_time_s(main_mrg, uuid_first_t_entry->metric);
time_t last_time_s = mrg_metric_get_latest_time_s(main_mrg, uuid_first_t_entry->metric);
time_t update_every_s = mrg_metric_get_update_every_s(main_mrg, uuid_first_t_entry->metric);
if (update_every_s && first_time_s && last_time_s) {
uint64_t remove_samples = (first_time_s - last_time_s) / update_every_s;
__atomic_sub_fetch(&ctx->atomic.samples, remove_samples, __ATOMIC_RELAXED);
}
bool deleted = mrg_metric_release_and_delete(main_mrg, uuid_first_t_entry->metric);
if(deleted)
deleted_metrics++;
else
zero_retention_referenced++;
}
else {
zero_disk_but_live++;
mrg_metric_release(main_mrg, uuid_first_t_entry->metric);
}
}
}
freez(uuid_first_entry_list);
internal_error(zero_disk_retention,
"DBENGINE: deleted %zu metrics, zero retention but referenced %zu (out of %zu total, of which %zu have main cache retention) zero on-disk retention tier %d metrics from metrics registry",
deleted_metrics, zero_retention_referenced, zero_disk_retention, zero_disk_but_live, ctx->config.tier);
if(global_first_time_s != LONG_MAX)
__atomic_store_n(&ctx->atomic.first_time_s, global_first_time_s, __ATOMIC_RELAXED);
if(worker)
worker_is_idle();
}
void datafile_delete(struct rrdengine_instance *ctx, struct rrdengine_datafile *datafile, bool update_retention, bool worker) {
if(worker)
worker_is_busy(UV_EVENT_DBENGINE_DATAFILE_DELETE_WAIT);
bool datafile_got_for_deletion = datafile_acquire_for_deletion(datafile, false);
if (update_retention)
update_metrics_first_time_s(ctx, datafile, datafile->next, worker);
while (!datafile_got_for_deletion) {
if(worker)
worker_is_busy(UV_EVENT_DBENGINE_DATAFILE_DELETE_WAIT);
datafile_got_for_deletion = datafile_acquire_for_deletion(datafile, false);
if (!datafile_got_for_deletion) {
netdata_log_info("DBENGINE: waiting for data file '%s/"
DATAFILE_PREFIX RRDENG_FILE_NUMBER_PRINT_TMPL DATAFILE_EXTENSION
"' to be available for deletion, "
"it is in use currently by %u users.",
ctx->config.dbfiles_path, ctx->datafiles.first->tier, ctx->datafiles.first->fileno, datafile->users.lockers);
__atomic_add_fetch(&rrdeng_cache_efficiency_stats.datafile_deletion_spin, 1, __ATOMIC_RELAXED);
sleep_usec(1 * USEC_PER_SEC);
}
}
__atomic_add_fetch(&rrdeng_cache_efficiency_stats.datafile_deletion_started, 1, __ATOMIC_RELAXED);
netdata_log_info("DBENGINE: deleting data file '%s/"
DATAFILE_PREFIX RRDENG_FILE_NUMBER_PRINT_TMPL DATAFILE_EXTENSION
"'.",
ctx->config.dbfiles_path, ctx->datafiles.first->tier, ctx->datafiles.first->fileno);
if(worker)
worker_is_busy(UV_EVENT_DBENGINE_DATAFILE_DELETE);
struct rrdengine_journalfile *journal_file;
unsigned deleted_bytes, journal_file_bytes, datafile_bytes;
int ret;
char path[RRDENG_PATH_MAX];
uv_rwlock_wrlock(&ctx->datafiles.rwlock);
datafile_list_delete_unsafe(ctx, datafile);
uv_rwlock_wrunlock(&ctx->datafiles.rwlock);
journal_file = datafile->journalfile;
datafile_bytes = datafile->pos;
journal_file_bytes = journalfile_current_size(journal_file);
deleted_bytes = journalfile_v2_data_size_get(journal_file);
netdata_log_info("DBENGINE: deleting data and journal files to maintain disk quota");
ret = journalfile_destroy_unsafe(journal_file, datafile);
if (!ret) {
journalfile_v1_generate_path(datafile, path, sizeof(path));
netdata_log_info("DBENGINE: deleted journal file \"%s\".", path);
journalfile_v2_generate_path(datafile, path, sizeof(path));
netdata_log_info("DBENGINE: deleted journal file \"%s\".", path);
deleted_bytes += journal_file_bytes;
}
ret = destroy_data_file_unsafe(datafile);
if (!ret) {
generate_datafilepath(datafile, path, sizeof(path));
netdata_log_info("DBENGINE: deleted data file \"%s\".", path);
deleted_bytes += datafile_bytes;
}
freez(journal_file);
freez(datafile);
ctx_current_disk_space_decrease(ctx, deleted_bytes);
netdata_log_info("DBENGINE: reclaimed %u bytes of disk space.", deleted_bytes);
}
static void *database_rotate_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *uv_work_req __maybe_unused) {
datafile_delete(ctx, ctx->datafiles.first, ctx_is_available_for_queries(ctx), true);
if (rrdeng_ctx_tier_cap_exceeded(ctx))
rrdeng_enq_cmd(ctx, RRDENG_OPCODE_DATABASE_ROTATE, NULL, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL);
rrdcontext_db_rotation();
return data;
}
static void after_flush_all_hot_and_dirty_pages_of_section(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* req __maybe_unused, int status __maybe_unused) {
;
}
static void *flush_all_hot_and_dirty_pages_of_section_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *uv_work_req __maybe_unused) {
worker_is_busy(UV_EVENT_DBENGINE_QUIESCE);
pgc_flush_all_hot_and_dirty_pages(main_cache, (Word_t)ctx);
completion_mark_complete(&ctx->quiesce.completion);
return data;
}
static void after_populate_mrg(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* req __maybe_unused, int status __maybe_unused) {
;
}
static void *populate_mrg_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *uv_work_req __maybe_unused) {
worker_is_busy(UV_EVENT_DBENGINE_POPULATE_MRG);
do {
struct rrdengine_datafile *datafile = NULL;
// find a datafile to work
uv_rwlock_rdlock(&ctx->datafiles.rwlock);
for(datafile = ctx->datafiles.first; datafile ; datafile = datafile->next) {
if(!spinlock_trylock(&datafile->populate_mrg.spinlock))
continue;
if(datafile->populate_mrg.populated) {
spinlock_unlock(&datafile->populate_mrg.spinlock);
continue;
}
// we have the spinlock and it is not populated
break;
}
uv_rwlock_rdunlock(&ctx->datafiles.rwlock);
if(!datafile)
break;
journalfile_v2_populate_retention_to_mrg(ctx, datafile->journalfile);
datafile->populate_mrg.populated = true;
spinlock_unlock(&datafile->populate_mrg.spinlock);
} while(1);
completion_mark_complete(completion);
return data;
}
static void after_ctx_shutdown(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* req __maybe_unused, int status __maybe_unused) {
;
}
static void *ctx_shutdown_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *uv_work_req __maybe_unused) {
worker_is_busy(UV_EVENT_DBENGINE_SHUTDOWN);
bool logged = false;
while(__atomic_load_n(&ctx->atomic.extents_currently_being_flushed, __ATOMIC_RELAXED) ||
__atomic_load_n(&ctx->atomic.inflight_queries, __ATOMIC_RELAXED)) {
if(!logged) {
logged = true;
netdata_log_info("DBENGINE: waiting for %zu inflight queries to finish to shutdown tier %d...",
__atomic_load_n(&ctx->atomic.inflight_queries, __ATOMIC_RELAXED), ctx->config.tier);
}
sleep_usec(1 * USEC_PER_MS);
}
completion_mark_complete(completion);
return data;
}
static void *cache_flush_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *uv_work_req __maybe_unused) {
if (!main_cache)
return data;
worker_is_busy(UV_EVENT_DBENGINE_FLUSH_MAIN_CACHE);
while (pgc_flush_pages(main_cache))
yield_the_processor();
return data;
}
static void *cache_evict_main_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *req __maybe_unused) {
if (!main_cache)
return data;
worker_is_busy(UV_EVENT_DBENGINE_EVICT_MAIN_CACHE);
while (pgc_evict_pages(main_cache, 0, 0))
yield_the_processor();
return data;
}
static void *cache_evict_open_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *req __maybe_unused) {
if (!open_cache)
return data;
worker_is_busy(UV_EVENT_DBENGINE_EVICT_OPEN_CACHE);
while (pgc_evict_pages(open_cache, 0, 0))
yield_the_processor();
return data;
}
static void *cache_evict_extent_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *req __maybe_unused) {
if (!extent_cache)
return data;
worker_is_busy(UV_EVENT_DBENGINE_EVICT_EXTENT_CACHE);
while (pgc_evict_pages(extent_cache, 0, 0))
yield_the_processor();
return data;
}
static void *query_prep_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *req __maybe_unused) {
PDC *pdc = data;
rrdeng_prep_query(pdc, true);
return data;
}
uint64_t rrdeng_target_data_file_size(struct rrdengine_instance *ctx) {
uint64_t target_size = ctx->config.max_disk_space ? ctx->config.max_disk_space / TARGET_DATAFILES : MAX_DATAFILE_SIZE;
target_size = MIN(target_size, MAX_DATAFILE_SIZE);
target_size = MAX(target_size, MIN_DATAFILE_SIZE);
return target_size;
}
time_t get_datafile_end_time(struct rrdengine_instance *ctx)
{
time_t last_time_s = 0;
uv_rwlock_rdlock(&ctx->datafiles.rwlock);
struct rrdengine_datafile *datafile = ctx->datafiles.first;
if (datafile) {
last_time_s = datafile->journalfile->v2.last_time_s;
if (!last_time_s)
last_time_s = datafile->journalfile->v2.first_time_s;
}
uv_rwlock_rdunlock(&ctx->datafiles.rwlock);
return last_time_s;
}
/* return 0 on success */
int init_rrd_files(struct rrdengine_instance *ctx)
{
return init_data_files(ctx);
}
void finalize_rrd_files(struct rrdengine_instance *ctx)
{
return finalize_data_files(ctx);
}
void async_cb(uv_async_t *handle)
{
uv_stop(handle->loop);
uv_update_time(handle->loop);
netdata_log_debug(D_RRDENGINE, "%s called, active=%d.", __func__, uv_is_active((uv_handle_t *)handle));
}
#define TIMER_PERIOD_MS (1000)
static void *extent_read_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *uv_work_req __maybe_unused) {
EPDL *epdl = data;
epdl_find_extent_and_populate_pages(ctx, epdl, true);
return data;
}
static void epdl_populate_pages_asynchronously(struct rrdengine_instance *ctx, EPDL *epdl, STORAGE_PRIORITY priority) {
rrdeng_enq_cmd(ctx, RRDENG_OPCODE_EXTENT_READ, epdl, NULL, priority,
rrdeng_enqueue_epdl_cmd, rrdeng_dequeue_epdl_cmd);
}
void pdc_route_asynchronously(struct rrdengine_instance *ctx, struct page_details_control *pdc) {
pdc_to_epdl_router(ctx, pdc, epdl_populate_pages_asynchronously, epdl_populate_pages_asynchronously);
}
void epdl_populate_pages_synchronously(struct rrdengine_instance *ctx, EPDL *epdl, enum storage_priority priority __maybe_unused) {
epdl_find_extent_and_populate_pages(ctx, epdl, false);
}
void pdc_route_synchronously(struct rrdengine_instance *ctx, struct page_details_control *pdc) {
pdc_to_epdl_router(ctx, pdc, epdl_populate_pages_synchronously, epdl_populate_pages_synchronously);
}
#define MAX_RETRIES_TO_START_INDEX (100)
static void *journal_v2_indexing_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *uv_work_req __maybe_unused) {
unsigned count = 0;
worker_is_busy(UV_EVENT_DBENGINE_JOURNAL_INDEX_WAIT);
while (__atomic_load_n(&ctx->atomic.now_deleting_files, __ATOMIC_RELAXED) && count++ < MAX_RETRIES_TO_START_INDEX)
sleep_usec(100 * USEC_PER_MS);
if (count == MAX_RETRIES_TO_START_INDEX) {
worker_is_idle();
return data;
}
struct rrdengine_datafile *datafile = ctx->datafiles.first;
worker_is_busy(UV_EVENT_DBENGINE_JOURNAL_INDEX);
count = 0;
while (datafile && datafile->fileno != ctx_last_fileno_get(ctx) && datafile->fileno != ctx_last_flush_fileno_get(ctx)) {
if(journalfile_v2_data_available(datafile->journalfile)) {
// journal file v2 is already there for this datafile
datafile = datafile->next;
continue;
}
spinlock_lock(&datafile->writers.spinlock);
bool available = (datafile->writers.running || datafile->writers.flushed_to_open_running) ? false : true;
spinlock_unlock(&datafile->writers.spinlock);
if(!available) {
nd_log(NDLS_DAEMON, NDLP_NOTICE,
"DBENGINE: journal file %u needs to be indexed, but it has writers working on it - "
"skipping it for now",
datafile->fileno);
datafile = datafile->next;
continue;
}
nd_log(NDLS_DAEMON, NDLP_DEBUG,
"DBENGINE: journal file %u is ready to be indexed",
datafile->fileno);
pgc_open_cache_to_journal_v2(open_cache, (Word_t) ctx, (int) datafile->fileno, ctx->config.page_type,
journalfile_migrate_to_v2_callback, (void *) datafile->journalfile);
count++;
datafile = datafile->next;
if (unlikely(!ctx_is_available_for_queries(ctx)))
break;
}
errno_clear();
if(count)
nd_log(NDLS_DAEMON, NDLP_DEBUG,
"DBENGINE: journal indexing done; %u files processed",
count);
worker_is_idle();
return data;
}
static void after_do_cache_flush(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* req __maybe_unused, int status __maybe_unused) {
rrdeng_main.flushes_running--;
}
static void after_do_main_cache_evict(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* req __maybe_unused, int status __maybe_unused) {
rrdeng_main.evict_main_running--;
}
static void after_do_open_cache_evict(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* req __maybe_unused, int status __maybe_unused) {
rrdeng_main.evict_open_running--;
}
static void after_do_extent_cache_evict(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* req __maybe_unused, int status __maybe_unused) {
rrdeng_main.evict_extent_running--;
}
static void after_journal_v2_indexing(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* req __maybe_unused, int status __maybe_unused) {
__atomic_store_n(&ctx->atomic.migration_to_v2_running, false, __ATOMIC_RELAXED);
rrdeng_enq_cmd(ctx, RRDENG_OPCODE_DATABASE_ROTATE, NULL, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL);
}
struct rrdeng_buffer_sizes rrdeng_get_buffer_sizes(void) {
return (struct rrdeng_buffer_sizes) {
.pgc = pgc_aral_overhead() + pgc_aral_structures(),
.pgd = pgd_aral_overhead() + pgd_aral_structures(),
.mrg = mrg_aral_overhead() + mrg_aral_structures(),
.opcodes = aral_overhead(rrdeng_main.cmd_queue.ar) + aral_structures(rrdeng_main.cmd_queue.ar),
.handles = aral_overhead(rrdeng_main.handles.ar) + aral_structures(rrdeng_main.handles.ar),
.descriptors = aral_overhead(rrdeng_main.descriptors.ar) + aral_structures(rrdeng_main.descriptors.ar),
.wal = __atomic_load_n(&wal_globals.atomics.allocated, __ATOMIC_RELAXED) * (sizeof(WAL) + RRDENG_BLOCK_SIZE),
.workers = aral_overhead(rrdeng_main.work_cmd.ar),
.pdc = pdc_cache_size(),
.xt_io = aral_overhead(rrdeng_main.xt_io_descr.ar) + aral_structures(rrdeng_main.xt_io_descr.ar),
.xt_buf = extent_buffer_cache_size(),
.epdl = epdl_cache_size(),
.deol = deol_cache_size(),
.pd = pd_cache_size(),
#ifdef PDC_USE_JULYL
.julyl = julyl_cache_size(),
#endif
};
}
static void after_cleanup(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t* req __maybe_unused, int status __maybe_unused) {
rrdeng_main.cleanup_running--;
}
static void *cleanup_tp_worker(struct rrdengine_instance *ctx __maybe_unused, void *data __maybe_unused, struct completion *completion __maybe_unused, uv_work_t *uv_work_req __maybe_unused) {
worker_is_busy(UV_EVENT_DBENGINE_BUFFERS_CLEANUP);
wal_cleanup1();
extent_buffer_cleanup1();
{
static time_t last_run_s = 0;
time_t now_s = now_monotonic_sec();
if(now_s - last_run_s >= 10) {
last_run_s = now_s;
journalfile_v2_data_unmount_cleanup(now_s);
}
}
#ifdef PDC_USE_JULYL
julyl_cleanup1();
#endif
return data;
}
uint64_t get_used_disk_space(struct rrdengine_instance *ctx)
{
uint64_t active_space = 0;
if (ctx->datafiles.first && ctx->datafiles.first->prev)
active_space = ctx->datafiles.first->prev->pos;
uint64_t estimated_disk_space = ctx_current_disk_space_get(ctx) + rrdeng_target_data_file_size(ctx) - active_space;
uint64_t database_space = get_total_database_space();
uint64_t adjusted_database_space = database_space * ctx->config.disk_percentage / 100 ;
estimated_disk_space += adjusted_database_space;
return estimated_disk_space;
}
static time_t get_tier_retention(struct rrdengine_instance *ctx)
{
time_t retention = 0;
if (localhost) {
STORAGE_ENGINE *eng = localhost->db[ctx->config.tier].eng;
if (eng) {
time_t first_time_s = get_datafile_end_time(ctx);
if (first_time_s)
retention = now_realtime_sec() - first_time_s;
}
}
return retention;
}
// Check if disk or retention time cap reached
bool rrdeng_ctx_tier_cap_exceeded(struct rrdengine_instance *ctx)
{
if(!ctx->datafiles.first)
// no datafiles available
return false;
if(!ctx->datafiles.first->next)
// only 1 datafile available
return false;
uint64_t estimated_disk_space = get_used_disk_space(ctx);
time_t retention = get_tier_retention(ctx);
if (ctx->config.max_retention_s && retention > ctx->config.max_retention_s)
return true;
if (ctx->config.max_disk_space && estimated_disk_space > ctx->config.max_disk_space)
return true;
return false;
}
static void retention_timer_cb(uv_timer_t *handle) {
if (!localhost)
return;
worker_is_busy(RRDENG_TIMER_CB);
uv_stop(handle->loop);
uv_update_time(handle->loop);
for (size_t tier = 0; tier < storage_tiers; tier++) {
STORAGE_ENGINE *eng = localhost->db[tier].eng;
if (!eng || eng->seb != STORAGE_ENGINE_BACKEND_DBENGINE)
continue;
bool cleanup = rrdeng_ctx_tier_cap_exceeded(multidb_ctx[tier]);
if (cleanup)
rrdeng_enq_cmd(multidb_ctx[tier], RRDENG_OPCODE_DATABASE_ROTATE, NULL, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL);
}
worker_is_idle();
}
static void timer_per_sec_cb(uv_timer_t* handle) {
worker_is_busy(RRDENG_TIMER_CB);
uv_stop(handle->loop);
uv_update_time(handle->loop);
worker_set_metric(RRDENG_OPCODES_WAITING, (NETDATA_DOUBLE)rrdeng_main.cmd_queue.unsafe.waiting);
worker_set_metric(RRDENG_WORKS_DISPATCHED, (NETDATA_DOUBLE)__atomic_load_n(&rrdeng_main.work_cmd.atomics.dispatched, __ATOMIC_RELAXED));
worker_set_metric(RRDENG_WORKS_EXECUTING, (NETDATA_DOUBLE)__atomic_load_n(&rrdeng_main.work_cmd.atomics.executing, __ATOMIC_RELAXED));
// rrdeng_enq_cmd(NULL, RRDENG_OPCODE_EVICT_MAIN, NULL, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL);
// rrdeng_enq_cmd(NULL, RRDENG_OPCODE_EVICT_OPEN, NULL, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL);
// rrdeng_enq_cmd(NULL, RRDENG_OPCODE_EVICT_EXTENT, NULL, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL);
rrdeng_enq_cmd(NULL, RRDENG_OPCODE_FLUSH_MAIN, NULL, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL);
rrdeng_enq_cmd(NULL, RRDENG_OPCODE_CLEANUP, NULL, NULL, STORAGE_PRIORITY_INTERNAL_DBENGINE, NULL, NULL);
worker_is_idle();
}
static void dbengine_initialize_structures(void) {
pgd_init_arals();
pgc_and_mrg_initialize();
pdc_init();
page_details_init();
epdl_init();
deol_init();
rrdeng_cmd_queue_init();
work_request_init();
rrdeng_query_handle_init();
page_descriptors_init();
extent_buffer_init();
extent_io_descriptor_init();
}
bool rrdeng_dbengine_spawn(struct rrdengine_instance *ctx __maybe_unused) {
static bool spawned = false;
static SPINLOCK spinlock = NETDATA_SPINLOCK_INITIALIZER;
spinlock_lock(&spinlock);
if(!spawned) {
int ret;
ret = uv_loop_init(&rrdeng_main.loop);
if (ret) {
netdata_log_error("DBENGINE: uv_loop_init(): %s", uv_strerror(ret));
return false;
}
rrdeng_main.loop.data = &rrdeng_main;
ret = uv_async_init(&rrdeng_main.loop, &rrdeng_main.async, async_cb);
if (ret) {
netdata_log_error("DBENGINE: uv_async_init(): %s", uv_strerror(ret));
fatal_assert(0 == uv_loop_close(&rrdeng_main.loop));
return false;
}
rrdeng_main.async.data = &rrdeng_main;
ret = uv_timer_init(&rrdeng_main.loop, &rrdeng_main.timer);
if (ret) {
netdata_log_error("DBENGINE: uv_timer_init(): %s", uv_strerror(ret));
uv_close((uv_handle_t *)&rrdeng_main.async, NULL);
fatal_assert(0 == uv_loop_close(&rrdeng_main.loop));
return false;
}
ret = uv_timer_init(&rrdeng_main.loop, &rrdeng_main.retention_timer);
if (ret) {
netdata_log_error("DBENGINE: uv_timer_init(): %s", uv_strerror(ret));
uv_close((uv_handle_t *)&rrdeng_main.async, NULL);
fatal_assert(0 == uv_loop_close(&rrdeng_main.loop));
return false;
}
rrdeng_main.timer.data = &rrdeng_main;
rrdeng_main.retention_timer.data = &rrdeng_main;
dbengine_initialize_structures();
fatal_assert(0 == uv_thread_create(&rrdeng_main.thread, dbengine_event_loop, &rrdeng_main));
spawned = true;
}
spinlock_unlock(&spinlock);
return true;
}
static inline void worker_dispatch_extent_read(struct rrdeng_cmd cmd, bool from_worker) {
struct rrdengine_instance *ctx = cmd.ctx;
EPDL *epdl = cmd.data;
if(from_worker)
epdl_find_extent_and_populate_pages(ctx, epdl, true);
else
work_dispatch(ctx, epdl, NULL, cmd.opcode, extent_read_tp_worker, NULL);
}
static inline void worker_dispatch_query_prep(struct rrdeng_cmd cmd, bool from_worker) {
struct rrdengine_instance *ctx = cmd.ctx;
PDC *pdc = cmd.data;
if(from_worker)
rrdeng_prep_query(pdc, true);
else
work_dispatch(ctx, pdc, NULL, cmd.opcode, query_prep_tp_worker, NULL);
}
uint64_t get_directory_free_bytes_space(struct rrdengine_instance *ctx)
{
uint64_t free_bytes = 0;
struct statvfs buff_statvfs;
if (statvfs(ctx->config.dbfiles_path, &buff_statvfs) == 0)
free_bytes = buff_statvfs.f_bavail * buff_statvfs.f_bsize;
return (free_bytes - (free_bytes * 5 / 100));
}
void calculate_tier_disk_space_percentage(void)
{
uint64_t tier_space[RRD_STORAGE_TIERS];
if (!localhost)
return;
uint64_t total_diskspace = 0;
for(size_t tier = 0; tier < storage_tiers ;tier++) {
STORAGE_ENGINE *eng = localhost->db[tier].eng;
if (!eng || eng->seb != STORAGE_ENGINE_BACKEND_DBENGINE) {
tier_space[tier] = 0;
continue;
}
uint64_t tier_disk_space = multidb_ctx[tier]->config.max_disk_space ?
multidb_ctx[tier]->config.max_disk_space :
get_directory_free_bytes_space(multidb_ctx[tier]);
total_diskspace += tier_disk_space;
tier_space[tier] = tier_disk_space;
}
if (total_diskspace) {
for (size_t tier = 0; tier < storage_tiers; tier++) {
multidb_ctx[tier]->config.disk_percentage = (100 * tier_space[tier] / total_diskspace);
}
}
}
void dbengine_retention_statistics(void)
{
static bool init = false;
static DBENGINE_TIER_STATS stats[RRD_STORAGE_TIERS];
if (!localhost)
return;
calculate_tier_disk_space_percentage();
for (size_t tier = 0; tier < storage_tiers; tier++) {
STORAGE_ENGINE *eng = localhost->db[tier].eng;
if (!eng || eng->seb != STORAGE_ENGINE_BACKEND_DBENGINE)
continue;
if (init == false) {
char id[200];
snprintfz(id, sizeof(id) - 1, "dbengine_retention_tier%zu", tier);
stats[tier].st = rrdset_create_localhost(
"netdata",
id,
NULL,
"dbengine retention",
"netdata.dbengine_tier_retention",
"dbengine space and time retention",
"%",
"netdata",
"stats",
134900, // before "dbengine memory" (dbengine2_statistics_charts)
10,
RRDSET_TYPE_LINE);
stats[tier].rd_space = rrddim_add(stats[tier].st, "space", NULL, 1, 1, RRD_ALGORITHM_ABSOLUTE);
stats[tier].rd_time = rrddim_add(stats[tier].st, "time", NULL, 1, 1, RRD_ALGORITHM_ABSOLUTE);
char tier_str[5];
snprintfz(tier_str, 4, "%zu", tier);
rrdlabels_add(stats[tier].st->rrdlabels, "tier", tier_str, RRDLABEL_SRC_AUTO);
rrdset_flag_set(stats[tier].st, RRDSET_FLAG_METADATA_UPDATE);
rrdhost_flag_set(stats[tier].st->rrdhost, RRDHOST_FLAG_METADATA_UPDATE);
rrdset_metadata_updated(stats[tier].st);
}
time_t first_time_s = storage_engine_global_first_time_s(eng->seb, localhost->db[tier].si);
time_t retention = first_time_s ? now_realtime_sec() - first_time_s : 0;
//
// Note: storage_engine_disk_space_used is the exact diskspace (as reported by api/v2/node_instances
// get_used_disk_space is used to determine if database cleanup (file rotation should happen)
// and adds to the disk space used the desired file size of the active
// datafile
uint64_t disk_space = get_used_disk_space(multidb_ctx[tier]);
//uint64_t disk_space = storage_engine_disk_space_used(eng->seb, localhost->db[tier].si);
uint64_t config_disk_space = storage_engine_disk_space_max(eng->seb, localhost->db[tier].si);
if (!config_disk_space) {
config_disk_space = get_directory_free_bytes_space(multidb_ctx[tier]);
config_disk_space += disk_space;
}
collected_number disk_percentage = (collected_number) (config_disk_space ? 100 * disk_space / config_disk_space : 0);
collected_number retention_percentage = (collected_number)multidb_ctx[tier]->config.max_retention_s ?
100 * retention / multidb_ctx[tier]->config.max_retention_s :
0;
if (retention_percentage > 100)
retention_percentage = 100;
rrddim_set_by_pointer(stats[tier].st, stats[tier].rd_space, (collected_number) disk_percentage);
rrddim_set_by_pointer(stats[tier].st, stats[tier].rd_time, (collected_number) retention_percentage);
rrdset_done(stats[tier].st);
}
init = true;
}
void dbengine_event_loop(void* arg) {
sanity_check();
uv_thread_set_name_np("DBENGINE");
service_register(SERVICE_THREAD_TYPE_EVENT_LOOP, NULL, NULL, NULL, true);
worker_register("DBENGINE");
// opcode jobs
worker_register_job_name(RRDENG_OPCODE_NOOP, "noop");
worker_register_job_name(RRDENG_OPCODE_QUERY, "query");
worker_register_job_name(RRDENG_OPCODE_EXTENT_WRITE, "extent write");
worker_register_job_name(RRDENG_OPCODE_EXTENT_READ, "extent read");
worker_register_job_name(RRDENG_OPCODE_FLUSHED_TO_OPEN, "flushed to open");
worker_register_job_name(RRDENG_OPCODE_DATABASE_ROTATE, "db rotate");
worker_register_job_name(RRDENG_OPCODE_JOURNAL_INDEX, "journal index");
worker_register_job_name(RRDENG_OPCODE_FLUSH_MAIN, "flush init");
worker_register_job_name(RRDENG_OPCODE_EVICT_MAIN, "evict init");
worker_register_job_name(RRDENG_OPCODE_CTX_SHUTDOWN, "ctx shutdown");
worker_register_job_name(RRDENG_OPCODE_CTX_QUIESCE, "ctx quiesce");
worker_register_job_name(RRDENG_OPCODE_SHUTDOWN_EVLOOP, "dbengine shutdown");
worker_register_job_name(RRDENG_OPCODE_MAX, "get opcode");
worker_register_job_name(RRDENG_OPCODE_MAX + RRDENG_OPCODE_QUERY, "query cb");
worker_register_job_name(RRDENG_OPCODE_MAX + RRDENG_OPCODE_EXTENT_WRITE, "extent write cb");
worker_register_job_name(RRDENG_OPCODE_MAX + RRDENG_OPCODE_EXTENT_READ, "extent read cb");
worker_register_job_name(RRDENG_OPCODE_MAX + RRDENG_OPCODE_FLUSHED_TO_OPEN, "flushed to open cb");
worker_register_job_name(RRDENG_OPCODE_MAX + RRDENG_OPCODE_DATABASE_ROTATE, "db rotate cb");
worker_register_job_name(RRDENG_OPCODE_MAX + RRDENG_OPCODE_JOURNAL_INDEX, "journal index cb");
worker_register_job_name(RRDENG_OPCODE_MAX + RRDENG_OPCODE_FLUSH_MAIN, "flush init cb");
worker_register_job_name(RRDENG_OPCODE_MAX + RRDENG_OPCODE_EVICT_MAIN, "evict init cb");
worker_register_job_name(RRDENG_OPCODE_MAX + RRDENG_OPCODE_CTX_SHUTDOWN, "ctx shutdown cb");
worker_register_job_name(RRDENG_OPCODE_MAX + RRDENG_OPCODE_CTX_QUIESCE, "ctx quiesce cb");
// special jobs
worker_register_job_name(RRDENG_TIMER_CB, "timer");
worker_register_job_name(RRDENG_FLUSH_TRANSACTION_BUFFER_CB, "transaction buffer flush cb");
worker_register_job_custom_metric(RRDENG_OPCODES_WAITING, "opcodes waiting", "opcodes", WORKER_METRIC_ABSOLUTE);
worker_register_job_custom_metric(RRDENG_WORKS_DISPATCHED, "works dispatched", "works", WORKER_METRIC_ABSOLUTE);
worker_register_job_custom_metric(RRDENG_WORKS_EXECUTING, "works executing", "works", WORKER_METRIC_ABSOLUTE);
struct rrdeng_main *main = arg;
enum rrdeng_opcode opcode;
struct rrdeng_cmd cmd;
main->tid = gettid_cached();
fatal_assert(0 == uv_timer_start(&main->timer, timer_per_sec_cb, TIMER_PERIOD_MS, TIMER_PERIOD_MS));
fatal_assert(0 == uv_timer_start(&main->retention_timer, retention_timer_cb, TIMER_PERIOD_MS * 60, TIMER_PERIOD_MS * 60));
bool shutdown = false;
while (likely(!shutdown)) {
worker_is_idle();
uv_run(&main->loop, UV_RUN_DEFAULT);
/* wait for commands */
do {
worker_is_busy(RRDENG_OPCODE_MAX);
cmd = rrdeng_deq_cmd(RRDENG_OPCODE_NOOP);
opcode = cmd.opcode;
worker_is_busy(opcode);
switch (opcode) {
case RRDENG_OPCODE_EXTENT_READ:
worker_dispatch_extent_read(cmd, false);
break;
case RRDENG_OPCODE_QUERY:
worker_dispatch_query_prep(cmd, false);
break;
case RRDENG_OPCODE_EXTENT_WRITE: {
struct rrdengine_instance *ctx = cmd.ctx;
struct page_descr_with_data *base = cmd.data;
struct completion *completion = cmd.completion; // optional
work_dispatch(ctx, base, completion, opcode, extent_write_tp_worker, after_extent_write);
break;
}
case RRDENG_OPCODE_FLUSHED_TO_OPEN: {
struct rrdengine_instance *ctx = cmd.ctx;
uv_fs_t *uv_fs_request = cmd.data;
struct extent_io_descriptor *xt_io_descr = uv_fs_request->data;
struct completion *completion = xt_io_descr->completion;
work_dispatch(ctx, uv_fs_request, completion, opcode, extent_flushed_to_open_tp_worker, after_extent_flushed_to_open);
break;
}
case RRDENG_OPCODE_FLUSH_MAIN: {
if(rrdeng_main.flushes_running < pgc_max_flushers()) {
rrdeng_main.flushes_running++;
work_dispatch(NULL, NULL, NULL, opcode, cache_flush_tp_worker, after_do_cache_flush);
}
break;
}
case RRDENG_OPCODE_EVICT_MAIN: {
if(rrdeng_main.evict_main_running < pgc_max_evictors()) {
rrdeng_main.evict_main_running++;
work_dispatch(NULL, NULL, NULL, opcode, cache_evict_main_tp_worker, after_do_main_cache_evict);
}
break;
}
case RRDENG_OPCODE_EVICT_OPEN: {
if(rrdeng_main.evict_open_running < pgc_max_evictors()) {
rrdeng_main.evict_open_running++;
work_dispatch(NULL, NULL, NULL, opcode, cache_evict_open_tp_worker, after_do_open_cache_evict);
}
break;
}
case RRDENG_OPCODE_EVICT_EXTENT: {
if(rrdeng_main.evict_extent_running < pgc_max_evictors()) {
rrdeng_main.evict_extent_running++;
work_dispatch(NULL, NULL, NULL, opcode, cache_evict_extent_tp_worker, after_do_extent_cache_evict);
}
break;
}
case RRDENG_OPCODE_CLEANUP: {
if(!rrdeng_main.cleanup_running) {
rrdeng_main.cleanup_running++;
work_dispatch(NULL, NULL, NULL, opcode, cleanup_tp_worker, after_cleanup);
}
break;
}
case RRDENG_OPCODE_JOURNAL_INDEX: {
struct rrdengine_instance *ctx = cmd.ctx;
struct rrdengine_datafile *datafile = cmd.data;
if(!__atomic_load_n(&ctx->atomic.migration_to_v2_running, __ATOMIC_RELAXED)) {
__atomic_store_n(&ctx->atomic.migration_to_v2_running, true, __ATOMIC_RELAXED);
work_dispatch(ctx, datafile, NULL, opcode, journal_v2_indexing_tp_worker, after_journal_v2_indexing);
}
break;
}
case RRDENG_OPCODE_DATABASE_ROTATE: {
struct rrdengine_instance *ctx = cmd.ctx;
if (!__atomic_load_n(&ctx->atomic.now_deleting_files, __ATOMIC_RELAXED) &&
ctx->datafiles.first->next != NULL &&
ctx->datafiles.first->next->next != NULL &&
rrdeng_ctx_tier_cap_exceeded(ctx)) {
__atomic_store_n(&ctx->atomic.now_deleting_files, true, __ATOMIC_RELAXED);
work_dispatch(ctx, NULL, NULL, opcode, database_rotate_tp_worker, after_database_rotate);
}
break;
}
case RRDENG_OPCODE_CTX_POPULATE_MRG: {
struct rrdengine_instance *ctx = cmd.ctx;
struct completion *completion = cmd.completion;
work_dispatch(ctx, NULL, completion, opcode, populate_mrg_tp_worker, after_populate_mrg);
break;
}
case RRDENG_OPCODE_CTX_QUIESCE: {
// a ctx will shutdown shortly
struct rrdengine_instance *ctx = cmd.ctx;
__atomic_store_n(&ctx->quiesce.enabled, true, __ATOMIC_RELEASE);
work_dispatch(ctx, NULL, NULL, opcode,
flush_all_hot_and_dirty_pages_of_section_tp_worker,
after_flush_all_hot_and_dirty_pages_of_section);
break;
}
case RRDENG_OPCODE_CTX_SHUTDOWN: {
// a ctx is shutting down
struct rrdengine_instance *ctx = cmd.ctx;
struct completion *completion = cmd.completion;
work_dispatch(ctx, NULL, completion, opcode, ctx_shutdown_tp_worker, after_ctx_shutdown);
break;
}
case RRDENG_OPCODE_SHUTDOWN_EVLOOP: {
uv_close((uv_handle_t *)&main->async, NULL);
(void) uv_timer_stop(&main->timer);
uv_close((uv_handle_t *)&main->timer, NULL);
(void) uv_timer_stop(&main->retention_timer);
uv_close((uv_handle_t *)&main->retention_timer, NULL);
shutdown = true;
break;
}
case RRDENG_OPCODE_NOOP: {
/* the command queue was empty, do nothing */
break;
}
// not opcodes
case RRDENG_OPCODE_MAX:
default: {
internal_fatal(true, "DBENGINE: unknown opcode");
break;
}
}
} while (opcode != RRDENG_OPCODE_NOOP);
}
nd_log(NDLS_DAEMON, NDLP_DEBUG, "Shutting down dbengine thread");
(void) uv_loop_close(&main->loop);
worker_unregister();
}