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// SPDX-License-Identifier: GPL-3.0-or-later
/** @file circular_buffer.c
* @brief This is the implementation of a circular buffer to be used
* for saving collected logs in memory, until they are stored
* into the database.
*/
#include "circular_buffer.h"
#include "helper.h"
#include "parser.h"
struct qsort_item {
Circ_buff_item_t *cbi;
struct File_info *pfi;
};
static int qsort_timestamp (const void *item_a, const void *item_b) {
return ( (int64_t)((struct qsort_item*)item_a)->cbi->timestamp -
(int64_t)((struct qsort_item*)item_b)->cbi->timestamp);
}
static int reverse_qsort_timestamp (const void * item_a, const void * item_b) {
return -qsort_timestamp(item_a, item_b);
}
/**
* @brief Search circular buffers according to the query_params.
* @details If multiple buffers are to be searched, the results will be sorted
* according to timestamps.
*
* Note that buff->tail can only be changed through circ_buff_read_done(), and
* circ_buff_search() and circ_buff_read_done() are mutually exclusive due
* to uv_mutex_lock() and uv_mutex_unlock() in queries and when writing to DB.
*
* @param p_query_params Query parameters to search according to.
* @param p_file_infos File_info structs to be searched.
*/
void circ_buff_search(logs_query_params_t *const p_query_params, struct File_info *const p_file_infos[]) {
for(int pfi_off = 0; p_file_infos[pfi_off]; pfi_off++)
uv_rwlock_rdlock(&p_file_infos[pfi_off]->circ_buff->buff_realloc_rwlock);
int buffs_size = 0,
buff_max_num_of_items = 0;
while(p_file_infos[buffs_size]){
if(p_file_infos[buffs_size]->circ_buff->num_of_items > buff_max_num_of_items)
buff_max_num_of_items = p_file_infos[buffs_size]->circ_buff->num_of_items;
buffs_size++;
}
struct qsort_item items[buffs_size * buff_max_num_of_items + 1]; // worst case allocation
int items_off = 0;
for(int buff_off = 0; p_file_infos[buff_off]; buff_off++){
Circ_buff_t *buff = p_file_infos[buff_off]->circ_buff;
/* TODO: The following 3 operations need to be replaced with a struct
* to gurantee atomicity. */
int head = __atomic_load_n(&buff->head, __ATOMIC_SEQ_CST) % buff->num_of_items;
int tail = __atomic_load_n(&buff->tail, __ATOMIC_SEQ_CST) % buff->num_of_items;
int full = __atomic_load_n(&buff->full, __ATOMIC_SEQ_CST);
if ((head == tail) && !full) continue; // Nothing to do if buff is empty
for (int i = tail; i != head; i = (i + 1) % buff->num_of_items){
items[items_off].cbi = &buff->items[i];
items[items_off++].pfi = p_file_infos[buff_off];
}
}
items[items_off].cbi = NULL;
items[items_off].pfi = NULL;
if(items[0].cbi)
qsort(items, items_off, sizeof(items[0]), p_query_params->order_by_asc ? qsort_timestamp : reverse_qsort_timestamp);
BUFFER *const res_buff = p_query_params->results_buff;
logs_query_res_hdr_t res_hdr = { // result header
.timestamp = p_query_params->act_to_ts,
.text_size = 0,
.matches = 0,
.log_source = "",
.log_type = ""
};
for (int i = 0; items[i].cbi; i++) {
/* If exceeding quota or timeout is reached and new timestamp is different than previous,
* terminate query but inform caller about act_to_ts to continue from (its next value) in next call. */
if( (res_buff->len >= p_query_params->quota || terminate_logs_manag_query(p_query_params)) &&
items[i].cbi->timestamp != res_hdr.timestamp){
p_query_params->act_to_ts = res_hdr.timestamp;
break;
}
res_hdr.timestamp = items[i].cbi->timestamp;
res_hdr.text_size = items[i].cbi->text_size;
strncpyz(res_hdr.log_source, log_src_t_str[items[i].pfi->log_source], sizeof(res_hdr.log_source) - 1);
strncpyz(res_hdr.log_type, log_src_type_t_str[items[i].pfi->log_type], sizeof(res_hdr.log_type) - 1);
strncpyz(res_hdr.basename, items[i].pfi->file_basename, sizeof(res_hdr.basename) - 1);
strncpyz(res_hdr.filename, items[i].pfi->filename, sizeof(res_hdr.filename) - 1);
strncpyz(res_hdr.chartname, items[i].pfi->chartname, sizeof(res_hdr.chartname) - 1);
if (p_query_params->order_by_asc ?
( res_hdr.timestamp >= p_query_params->req_from_ts && res_hdr.timestamp <= p_query_params->req_to_ts ) :
( res_hdr.timestamp >= p_query_params->req_to_ts && res_hdr.timestamp <= p_query_params->req_from_ts) ){
/* In case of search_keyword, less than sizeof(res_hdr) + temp_msg.text_size
* space is required, but go for worst case scenario for now */
buffer_increase(res_buff, sizeof(res_hdr) + res_hdr.text_size);
if(!p_query_params->keyword || !*p_query_params->keyword || !strcmp(p_query_params->keyword, " ")){
/* NOTE: relying on items[i]->cbi->num_lines to get number of log lines
* might not be 100% correct, since parsing must have taken place
* already to return correct count. Maybe an issue under heavy load. */
res_hdr.matches = items[i].cbi->num_lines;
memcpy(&res_buff->buffer[res_buff->len + sizeof(res_hdr)], items[i].cbi->data, res_hdr.text_size);
}
else {
res_hdr.matches = search_keyword( items[i].cbi->data, res_hdr.text_size,
&res_buff->buffer[res_buff->len + sizeof(res_hdr)],
&res_hdr.text_size, p_query_params->keyword, NULL,
p_query_params->ignore_case);
m_assert( (res_hdr.matches > 0 && res_hdr.text_size > 0) ||
(res_hdr.matches == 0 && res_hdr.text_size == 0),
"res_hdr.matches and res_hdr.text_size must both be > 0 or == 0.");
if(unlikely(res_hdr.matches < 0))
break; /* res_hdr.matches < 0 - error during keyword search */
}
if(res_hdr.text_size){
res_buff->buffer[res_buff->len + sizeof(res_hdr) + res_hdr.text_size - 1] = '\n'; // replace '\0' with '\n'
memcpy(&res_buff->buffer[res_buff->len], &res_hdr, sizeof(res_hdr));
res_buff->len += sizeof(res_hdr) + res_hdr.text_size;
p_query_params->num_lines += res_hdr.matches;
}
m_assert(TEST_MS_TIMESTAMP_VALID(res_hdr.timestamp), "res_hdr.timestamp is invalid");
}
}
for(int pfi_off = 0; p_file_infos[pfi_off]; pfi_off++)
uv_rwlock_rdunlock(&p_file_infos[pfi_off]->circ_buff->buff_realloc_rwlock);
}
/**
* @brief Query circular buffer if there is space for item insertion.
* @param buff Circular buffer to query for available space.
* @param requested_text_space Size of raw (uncompressed) space needed.
* @note If buff->allow_dropped_logs is 0, then this function will block and
* it will only return once there is available space as requested. In this
* case, it will never return 0.
* @return \p requested_text_space if there is enough space, else 0.
*/
size_t circ_buff_prepare_write(Circ_buff_t *const buff, size_t const requested_text_space){
/* Calculate how much is the maximum compressed space that will
* be required on top of the requested space for the raw data. */
buff->in->text_compressed_size = (size_t) LZ4_compressBound(requested_text_space);
m_assert(buff->in->text_compressed_size != 0, "requested text compressed space is zero");
size_t const required_space = requested_text_space + buff->in->text_compressed_size;
size_t available_text_space = 0;
size_t total_cached_mem_ex_in;
try_to_acquire_space:
total_cached_mem_ex_in = 0;
for (int i = 0; i < buff->num_of_items; i++){
total_cached_mem_ex_in += buff->items[i].data_max_size;
}
/* If the required space is more than the allocated space of the input
* buffer, then we need to check if the input buffer can be reallocated:
*
* a) If the total memory consumption of the circular buffer plus the
* required space is less than the limit set by "circular buffer max size"
* for this log source, then the input buffer can be reallocated.
*
* b) If the total memory consumption of the circular buffer plus the
* required space is more than the limit set by "circular buffer max size"
* for this log source, we will attempt to reclaim some of the circular
* buffer allocated memory from any empty items.
*
* c) If after reclaiming the total memory consumption is still beyond the
* configuration limit, either 0 will be returned as the available space
* for raw logs in the input buffer, or the function will block and repeat
* the same process, until there is available space to be returned, depending
* of the configuration value of buff->allow_dropped_logs.
* */
if(required_space > buff->in->data_max_size) {
if(likely(total_cached_mem_ex_in + required_space <= buff->total_cached_mem_max)){
buff->in->data_max_size = required_space;
buff->in->data = reallocz(buff->in->data, buff->in->data_max_size);
available_text_space = requested_text_space;
}
else if(likely(__atomic_load_n(&buff->full, __ATOMIC_SEQ_CST) == 0)){
int head = __atomic_load_n(&buff->head, __ATOMIC_SEQ_CST) % buff->num_of_items;
int tail = __atomic_load_n(&buff->tail, __ATOMIC_SEQ_CST) % buff->num_of_items;
for (int i = (head == tail ? (head + 1) % buff->num_of_items : head);
i != tail; i = (i + 1) % buff->num_of_items) {
m_assert(i <= buff->num_of_items, "i > buff->num_of_items");
buff->items[i].data_max_size = 1;
buff->items[i].data = reallocz(buff->items[i].data, buff->items[i].data_max_size);
}
total_cached_mem_ex_in = 0;
for (int i = 0; i < buff->num_of_items; i++){
total_cached_mem_ex_in += buff->items[i].data_max_size;
}
if(total_cached_mem_ex_in + required_space <= buff->total_cached_mem_max){
buff->in->data_max_size = required_space;
buff->in->data = reallocz(buff->in->data, buff->in->data_max_size);
available_text_space = requested_text_space;
}
else available_text_space = 0;
}
} else available_text_space = requested_text_space;
__atomic_store_n(&buff->total_cached_mem, total_cached_mem_ex_in + buff->in->data_max_size, __ATOMIC_RELAXED);
if(unlikely(!buff->allow_dropped_logs && !available_text_space)){
sleep_usec(CIRC_BUFF_PREP_WR_RETRY_AFTER_MS * USEC_PER_MS);
goto try_to_acquire_space;
}
m_assert(available_text_space || buff->allow_dropped_logs, "!available_text_space == 0 && !buff->allow_dropped_logs");
return available_text_space;
}
/**
* @brief Insert item from temporary input buffer to circular buffer.
* @param buff Circular buffer to insert the item into
* @return 0 in case of success or -1 in case there was an error (e.g. buff
* is out of space).
*/
int circ_buff_insert(Circ_buff_t *const buff){
// TODO: Probably can be changed to __ATOMIC_RELAXED, but ideally a mutex should be used here.
int head = __atomic_load_n(&buff->head, __ATOMIC_SEQ_CST) % buff->num_of_items;
int tail = __atomic_load_n(&buff->tail, __ATOMIC_SEQ_CST) % buff->num_of_items;
int full = __atomic_load_n(&buff->full, __ATOMIC_SEQ_CST);
/* If circular buffer does not have any free items, it will be expanded
* by reallocating the `items` array and adding one more item. */
if (unlikely(( head == tail ) && full )) {
debug_log( "buff out of space! will be expanded.");
uv_rwlock_wrlock(&buff->buff_realloc_rwlock);
Circ_buff_item_t *items_new = callocz(buff->num_of_items + 1, sizeof(Circ_buff_item_t));
for(int i = 0; i < buff->num_of_items; i++){
Circ_buff_item_t *item_old = &buff->items[head++ % buff->num_of_items];
items_new[i] = *item_old;
}
freez(buff->items);
buff->items = items_new;
buff->parse = buff->parse - buff->tail;
head = buff->head = buff->num_of_items++;
buff->tail = buff->read = 0;
buff->full = 0;
__atomic_add_fetch(&buff->buff_realloc_cnt, 1, __ATOMIC_RELAXED);
uv_rwlock_wrunlock(&buff->buff_realloc_rwlock);
}
Circ_buff_item_t *cur_item = &buff->items[head];
char *tmp_data = cur_item->data;
size_t tmp_data_max_size = cur_item->data_max_size;
cur_item->status = buff->in->status;
cur_item->timestamp = buff->in->timestamp;
cur_item->data = buff->in->data;
cur_item->text_size = buff->in->text_size;
cur_item->text_compressed = buff->in->text_compressed;
cur_item->text_compressed_size = buff->in->text_compressed_size;
cur_item->data_max_size = buff->in->data_max_size;
cur_item->num_lines = buff->in->num_lines;
buff->in->status = CIRC_BUFF_ITEM_STATUS_UNPROCESSED;
buff->in->timestamp = 0;
buff->in->data = tmp_data;
buff->in->text_size = 0;
// buff->in->text_compressed = tmp_data;
buff->in->text_compressed_size = 0;
buff->in->data_max_size = tmp_data_max_size;
buff->in->num_lines = 0;
__atomic_add_fetch(&buff->text_size_total, cur_item->text_size, __ATOMIC_SEQ_CST);
if( __atomic_add_fetch(&buff->text_compressed_size_total, cur_item->text_compressed_size, __ATOMIC_SEQ_CST)){
__atomic_store_n(&buff->compression_ratio,
__atomic_load_n(&buff->text_size_total, __ATOMIC_SEQ_CST) /
__atomic_load_n(&buff->text_compressed_size_total, __ATOMIC_SEQ_CST),
__ATOMIC_SEQ_CST);
} else __atomic_store_n( &buff->compression_ratio, 0, __ATOMIC_SEQ_CST);
if(unlikely(__atomic_add_fetch(&buff->head, 1, __ATOMIC_SEQ_CST) % buff->num_of_items ==
__atomic_load_n(&buff->tail, __ATOMIC_SEQ_CST) % buff->num_of_items)){
__atomic_store_n(&buff->full, 1, __ATOMIC_SEQ_CST);
}
__atomic_or_fetch(&cur_item->status, CIRC_BUFF_ITEM_STATUS_PARSED | CIRC_BUFF_ITEM_STATUS_STREAMED, __ATOMIC_SEQ_CST);
return 0;
}
/**
* @brief Return pointer to next item to be read from the circular buffer.
* @param buff Circular buffer to get next item from.
* @return Pointer to the next circular buffer item to be read, or NULL
* if there are no more items to be read.
*/
Circ_buff_item_t *circ_buff_read_item(Circ_buff_t *const buff) {
Circ_buff_item_t *item = &buff->items[buff->read % buff->num_of_items];
m_assert(__atomic_load_n(&item->status, __ATOMIC_RELAXED) <= CIRC_BUFF_ITEM_STATUS_DONE, "Invalid status");
if( /* No more records to be retrieved from the buffer - pay attention that
* there is no `% buff->num_of_items` operation, as we need to check
* the case where buff->read is exactly equal to buff->head. */
(buff->read == (__atomic_load_n(&buff->head, __ATOMIC_SEQ_CST))) ||
/* Current item either not parsed or streamed */
(__atomic_load_n(&item->status, __ATOMIC_RELAXED) != CIRC_BUFF_ITEM_STATUS_DONE) ){
return NULL;
}
__atomic_sub_fetch(&buff->text_size_total, item->text_size, __ATOMIC_SEQ_CST);
if( __atomic_sub_fetch(&buff->text_compressed_size_total, item->text_compressed_size, __ATOMIC_SEQ_CST)){
__atomic_store_n(&buff->compression_ratio,
__atomic_load_n(&buff->text_size_total, __ATOMIC_SEQ_CST) /
__atomic_load_n(&buff->text_compressed_size_total, __ATOMIC_SEQ_CST),
__ATOMIC_SEQ_CST);
} else __atomic_store_n( &buff->compression_ratio, 0, __ATOMIC_SEQ_CST);
buff->read++;
return item;
}
/**
* @brief Complete buffer read process.
* @param buff Circular buffer to complete read process on.
*/
void circ_buff_read_done(Circ_buff_t *const buff){
/* Even if one item was read, it means buffer cannot be full anymore */
if(__atomic_load_n(&buff->tail, __ATOMIC_RELAXED) != buff->read)
__atomic_store_n(&buff->full, 0, __ATOMIC_SEQ_CST);
__atomic_store_n(&buff->tail, buff->read, __ATOMIC_SEQ_CST);
}
/**
* @brief Create a new circular buffer.
* @param num_of_items Number of Circ_buff_item_t items in the buffer.
* @param max_size Maximum memory the circular buffer can occupy.
* @param allow_dropped_logs Maximum memory the circular buffer can occupy.
* @return Pointer to the new circular buffer structure.
*/
Circ_buff_t *circ_buff_init(const int num_of_items,
const size_t max_size,
const int allow_dropped_logs ) {
Circ_buff_t *buff = callocz(1, sizeof(Circ_buff_t));
buff->num_of_items = num_of_items;
buff->items = callocz(buff->num_of_items, sizeof(Circ_buff_item_t));
buff->in = callocz(1, sizeof(Circ_buff_item_t));
uv_rwlock_init(&buff->buff_realloc_rwlock);
buff->total_cached_mem_max = max_size;
buff->allow_dropped_logs = allow_dropped_logs;
return buff;
}
/**
* @brief Destroy a circular buffer.
* @param buff Circular buffer to be destroyed.
*/
void circ_buff_destroy(Circ_buff_t *buff){
for (int i = 0; i < buff->num_of_items; i++) freez(buff->items[i].data);
freez(buff->items);
freez(buff->in->data);
freez(buff->in);
freez(buff);
};
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