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netdata_netdata/libnetdata/string/string.c
Costa Tsaousis f2b250a1f5
dyncfg v2 () 
* split rrdfunctions streaming and progress

* simplified internal inline functions API

* split rrdfunctions inflight management

* split rrd functions exporters

* renames

* base dyncfg structure

* config pluginsd

* intercept dyncfg function calls

* loading and saving of dyncfg metadata and data

* save metadata and payload to a single file; added code to update the plugins with jobs and saved configs

* basic working unit test

* added payload to functions execution

* removed old dyncfg code that is not needed any more

* more cleanup

* cleanup sender for functions with payload

* dyncfg functions are not exposed as functions

* remaining work to avoid indexing the \0 terminating character in dictionary keys

* added back old dyncfg plugins.d commands as noop, to allow plugins continue working

* working api; working streaming;

* updated plugins.d documentation

* aclk and http api requests share the same header parsing logic

* added source type internal

* fixed crashes

* added god mode for tests

* fixes

* fixed messages

* save host machine guids to configs

* cleaner manipulation of supported commands

* the functions event loop for external plugins can now process dyncfg requests

* unified internal and external plugins dyncfg API

* Netdata serves schema requests from /etc/netdata/schema.d and /var/lib/netdata/conf.d/schema.d

* cleanup and various fixes; fixed bug in previous dyncfg implementation on streaming that was sending the paylod in a way that allowed other streaming commands to be multiplexed

* internals go to a separate header file

* fix duplicate ACLK requests sent by aclk queue mechanism

* use fstat instead of stat

* working api

* plugin actions renamed to create and delete; dyncfg files are removed only from user actions

* prevent deadlock by using the react callback

* fix for string_strndupz()

* better dyncfg unittests

* more tests at the unittests

* properly detect dyncfg functions

* hide config functions from the UI

* tree response improvements

* send the initial update with payload

* determine tty using stdout, not stderr

* changes to statuses, cleanup and the code to bring all business logic into interception

* do not crash when the status is empty

* functions now propagate the source of the requests to plugins

* avoid warning about unused functions

* in the count at items for attention, do not count the orphan entries

* save source into dyncfg

* make the list null terminated

* fixed invalid comparison

* prevent memory leak on duplicated headers; log x-forwarded-for

* more unit tests

* added dyncfg unittests into the default unittests

* more unit tests and fixes

* more unit tests and fixes

* fix dictionary unittests

* config functions require admin access
2024-01-11 16:56:45 +02:00

707 lines
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// SPDX-License-Identifier: GPL-3.0-or-later
#include "../libnetdata.h"
#include <Judy.h>
typedef int32_t REFCOUNT;
// ----------------------------------------------------------------------------
// STRING implementation - dedup all STRING
#define STRING_PARTITION_SHIFTS (0)
#define STRING_PARTITIONS (256 >> STRING_PARTITION_SHIFTS)
#define string_partition_str(str) ((uint8_t)((str)[0]) >> STRING_PARTITION_SHIFTS)
#define string_partition(string) (string_partition_str((string)->str))
struct netdata_string {
uint32_t length; // the string length including the terminating '\0'
REFCOUNT refcount; // how many times this string is used
// We use a signed number to be able to detect duplicate frees of a string.
// If at any point this goes below zero, we have a duplicate free.
const char str[]; // the string itself, is appended to this structure
};
static struct string_partition {
RW_SPINLOCK spinlock; // the R/W spinlock to protect the Judy array
Pvoid_t JudyHSArray; // the Judy array - hashtable
size_t inserts; // the number of successful inserts to the index
size_t deletes; // the number of successful deleted from the index
long int entries; // the number of entries in the index
long int memory; // the memory used, without the JudyHS index
#ifdef NETDATA_INTERNAL_CHECKS
// internal statistics
struct {
size_t searches; // the number of successful searches in the index
size_t releases; // when a string is unreferenced
size_t duplications; // when a string is referenced
long int active_references; // the number of active references alive
} atomic;
size_t found_deleted_on_search;
size_t found_available_on_search;
size_t found_deleted_on_insert;
size_t found_available_on_insert;
size_t spins;
#endif
} string_base[STRING_PARTITIONS] = { 0 };
#ifdef NETDATA_INTERNAL_CHECKS
#define string_stats_atomic_increment(partition, var) __atomic_add_fetch(&string_base[partition].atomic.var, 1, __ATOMIC_RELAXED)
#define string_stats_atomic_decrement(partition, var) __atomic_sub_fetch(&string_base[partition].atomic.var, 1, __ATOMIC_RELAXED)
#define string_internal_stats_add(partition, var, val) __atomic_add_fetch(&string_base[partition].var, val, __ATOMIC_RELAXED)
#else
#define string_stats_atomic_increment(partition, var) do {;} while(0)
#define string_stats_atomic_decrement(partition, var) do {;} while(0)
#define string_internal_stats_add(partition, var, val) do {;} while(0)
#endif
void string_statistics(size_t *inserts, size_t *deletes, size_t *searches, size_t *entries, size_t *references, size_t *memory, size_t *duplications, size_t *releases) {
if (inserts) *inserts = 0;
if (deletes) *deletes = 0;
if (searches) *searches = 0;
if (entries) *entries = 0;
if (references) *references = 0;
if (memory) *memory = 0;
if (duplications) *duplications = 0;
if (releases) *releases = 0;
for(size_t i = 0; i < STRING_PARTITIONS ;i++) {
if (inserts) *inserts += string_base[i].inserts;
if (deletes) *deletes += string_base[i].deletes;
if (entries) *entries += (size_t) string_base[i].entries;
if (memory) *memory += (size_t) string_base[i].memory;
#ifdef NETDATA_INTERNAL_CHECKS
if (searches) *searches += string_base[i].atomic.searches;
if (references) *references += (size_t) string_base[i].atomic.active_references;
if (duplications) *duplications += string_base[i].atomic.duplications;
if (releases) *releases += string_base[i].atomic.releases;
#endif
}
}
#define string_entry_acquire(se) __atomic_add_fetch(&((se)->refcount), 1, __ATOMIC_SEQ_CST)
#define string_entry_release(se) __atomic_sub_fetch(&((se)->refcount), 1, __ATOMIC_SEQ_CST)
static inline bool string_entry_check_and_acquire(STRING *se) {
#ifdef NETDATA_INTERNAL_CHECKS
uint8_t partition = string_partition(se);
#endif
REFCOUNT expected, desired, count = 0;
expected = __atomic_load_n(&se->refcount, __ATOMIC_SEQ_CST);
do {
count++;
if(expected <= 0) {
// We cannot use this.
// The reference counter reached value zero,
// so another thread is deleting this.
string_internal_stats_add(partition, spins, count - 1);
return false;
}
desired = expected + 1;
} while(!__atomic_compare_exchange_n(&se->refcount, &expected, desired, false, __ATOMIC_SEQ_CST, __ATOMIC_SEQ_CST));
string_internal_stats_add(partition, spins, count - 1);
// statistics
// string_base.active_references is altered at the in string_strdupz() and string_freez()
string_stats_atomic_increment(partition, duplications);
return true;
}
STRING *string_dup(STRING *string) {
if(unlikely(!string)) return NULL;
#ifdef NETDATA_INTERNAL_CHECKS
if(unlikely(__atomic_load_n(&string->refcount, __ATOMIC_SEQ_CST) <= 0))
fatal("STRING: tried to %s() a string that is freed (it has %d references).", __FUNCTION__, string->refcount);
#endif
string_entry_acquire(string);
#ifdef NETDATA_INTERNAL_CHECKS
uint8_t partition = string_partition(string);
#endif
// statistics
string_stats_atomic_increment(partition, active_references);
string_stats_atomic_increment(partition, duplications);
return string;
}
// Search the index and return an ACQUIRED string entry, or NULL
static inline STRING *string_index_search(const char *str, size_t length) {
STRING *string;
uint8_t partition = string_partition_str(str);
// Find the string in the index
// With a read-lock so that multiple readers can use the index concurrently.
rw_spinlock_read_lock(&string_base[partition].spinlock);
Pvoid_t *Rc;
Rc = JudyHSGet(string_base[partition].JudyHSArray, (void *)str, length - 1);
if(likely(Rc)) {
// found in the hash table
string = *Rc;
if(string_entry_check_and_acquire(string)) {
// we can use this entry
string_internal_stats_add(partition, found_available_on_search, 1);
}
else {
// this entry is about to be deleted by another thread
// do not touch it, let it go...
string = NULL;
string_internal_stats_add(partition, found_deleted_on_search, 1);
}
}
else {
// not found in the hash table
string = NULL;
}
string_stats_atomic_increment(partition, searches);
rw_spinlock_read_unlock(&string_base[partition].spinlock);
return string;
}
// Insert a string to the index and return an ACQUIRED string entry,
// or NULL if the call needs to be retried (a deleted entry with the same key is still in the index)
// The returned entry is ACQUIRED, and it can either be:
// 1. a new item inserted, or
// 2. an item found in the index that is not currently deleted
static inline STRING *string_index_insert(const char *str, size_t length) {
STRING *string;
uint8_t partition = string_partition_str(str);
rw_spinlock_write_lock(&string_base[partition].spinlock);
STRING **ptr;
{
JError_t J_Error;
Pvoid_t *Rc = JudyHSIns(&string_base[partition].JudyHSArray, (void *)str, length - 1, &J_Error);
if (unlikely(Rc == PJERR)) {
fatal(
"STRING: Cannot insert entry with name '%s' to JudyHS, JU_ERRNO_* == %u, ID == %d",
str,
JU_ERRNO(&J_Error),
JU_ERRID(&J_Error));
}
ptr = (STRING **)Rc;
}
if (likely(*ptr == 0)) {
// a new item added to the index
size_t mem_size = sizeof(STRING) + length;
string = mallocz(mem_size);
strcpy((char *)string->str, str);
string->length = length;
string->refcount = 1;
*ptr = string;
string_base[partition].inserts++;
string_base[partition].entries++;
string_base[partition].memory += (long)(mem_size + JUDYHS_INDEX_SIZE_ESTIMATE(length));
}
else {
// the item is already in the index
string = *ptr;
if(string_entry_check_and_acquire(string)) {
// we can use this entry
string_internal_stats_add(partition, found_available_on_insert, 1);
}
else {
// this entry is about to be deleted by another thread
// do not touch it, let it go...
string = NULL;
string_internal_stats_add(partition, found_deleted_on_insert, 1);
}
string_stats_atomic_increment(partition, searches);
}
rw_spinlock_write_unlock(&string_base[partition].spinlock);
return string;
}
// delete an entry from the index
static inline void string_index_delete(STRING *string) {
uint8_t partition = string_partition(string);
rw_spinlock_write_lock(&string_base[partition].spinlock);
#ifdef NETDATA_INTERNAL_CHECKS
if(unlikely(__atomic_load_n(&string->refcount, __ATOMIC_SEQ_CST) != 0))
fatal("STRING: tried to delete a string at %s() that is already freed (it has %d references).", __FUNCTION__, string->refcount);
#endif
bool deleted = false;
if (likely(string_base[partition].JudyHSArray)) {
JError_t J_Error;
int ret = JudyHSDel(&string_base[partition].JudyHSArray, (void *)string->str, string->length - 1, &J_Error);
if (unlikely(ret == JERR)) {
netdata_log_error(
"STRING: Cannot delete entry with name '%s' from JudyHS, JU_ERRNO_* == %u, ID == %d",
string->str,
JU_ERRNO(&J_Error),
JU_ERRID(&J_Error));
} else
deleted = true;
}
if (unlikely(!deleted))
netdata_log_error("STRING: tried to delete '%s' that is not in the index. Ignoring it.", string->str);
else {
size_t mem_size = sizeof(STRING) + string->length;
string_base[partition].deletes++;
string_base[partition].entries--;
string_base[partition].memory -= (long)(mem_size + JUDYHS_INDEX_SIZE_ESTIMATE(string->length));
freez(string);
}
rw_spinlock_write_unlock(&string_base[partition].spinlock);
}
STRING *string_strdupz(const char *str) {
if(unlikely(!str || !*str)) return NULL;
#ifdef NETDATA_INTERNAL_CHECKS
uint8_t partition = string_partition_str(str);
#endif
size_t length = strlen(str) + 1;
STRING *string = string_index_search(str, length);
while(!string) {
// The search above did not find anything,
// We loop here, because during insert we may find an entry that is being deleted by another thread.
// So, we have to let it go and retry to insert it again.
string = string_index_insert(str, length);
}
// statistics
string_stats_atomic_increment(partition, active_references);
return string;
}
STRING *string_strndupz(const char *str, size_t len) {
if(unlikely(!str || !*str || !len)) return NULL;
#ifdef NETDATA_INTERNAL_CHECKS
uint8_t partition = string_partition_str(str);
#endif
char buf[len + 1];
memcpy(buf, str, len);
buf[len] = '\0';
STRING *string = string_index_search(buf, len + 1);
while(!string)
string = string_index_insert(buf, len + 1);
string_stats_atomic_increment(partition, active_references);
return string;
}
void string_freez(STRING *string) {
if(unlikely(!string)) return;
#ifdef NETDATA_INTERNAL_CHECKS
uint8_t partition = string_partition(string);
#endif
REFCOUNT refcount = string_entry_release(string);
#ifdef NETDATA_INTERNAL_CHECKS
if(unlikely(refcount < 0))
fatal("STRING: tried to %s() a string that is already freed (it has %d references).", __FUNCTION__, string->refcount);
#endif
if(unlikely(refcount == 0))
string_index_delete(string);
// statistics
string_stats_atomic_decrement(partition, active_references);
string_stats_atomic_increment(partition, releases);
}
inline size_t string_strlen(STRING *string) {
if(unlikely(!string)) return 0;
return string->length - 1;
}
inline const char *string2str(STRING *string) {
if(unlikely(!string)) return "";
return string->str;
}
STRING *string_2way_merge(STRING *a, STRING *b) {
static STRING *X = NULL;
if(unlikely(!X)) {
X = string_strdupz("[x]");
}
if(unlikely(a == b)) return string_dup(a);
if(unlikely(a == X)) return string_dup(a);
if(unlikely(b == X)) return string_dup(b);
if(unlikely(!a)) return string_dup(X);
if(unlikely(!b)) return string_dup(X);
size_t alen = string_strlen(a);
size_t blen = string_strlen(b);
size_t length = alen + blen + string_strlen(X) + 1;
char buf1[length + 1], buf2[length + 1], *dst1;
const char *s1, *s2;
s1 = string2str(a);
s2 = string2str(b);
dst1 = buf1;
for( ; *s1 && *s2 && *s1 == *s2 ;s1++, s2++)
*dst1++ = *s1;
*dst1 = '\0';
if(*s1 != '\0' || *s2 != '\0') {
*dst1++ = '[';
*dst1++ = 'x';
*dst1++ = ']';
s1 = &(string2str(a))[alen - 1];
s2 = &(string2str(b))[blen - 1];
char *dst2 = &buf2[length];
*dst2 = '\0';
for (; *s1 && *s2 && *s1 == *s2; s1--, s2--)
*(--dst2) = *s1;
strcpy(dst1, dst2);
}
return string_strdupz(buf1);
}
// ----------------------------------------------------------------------------
// STRING unit test
struct thread_unittest {
int join;
int dups;
};
static void *string_thread(void *arg) {
struct thread_unittest *tu = arg;
for(; 1 ;) {
if(__atomic_load_n(&tu->join, __ATOMIC_RELAXED))
break;
STRING *s = string_strdupz("string thread checking 1234567890");
for(int i = 0; i < tu->dups ; i++)
string_dup(s);
for(int i = 0; i < tu->dups ; i++)
string_freez(s);
string_freez(s);
}
return arg;
}
static char **string_unittest_generate_names(size_t entries) {
char **names = mallocz(sizeof(char *) * entries);
for(size_t i = 0; i < entries ;i++) {
char buf[25 + 1] = "";
snprintfz(buf, sizeof(buf) - 1, "name.%zu.0123456789.%zu \t !@#$%%^&*(),./[]{}\\|~`", i, entries / 2 + i);
names[i] = strdupz(buf);
}
return names;
}
static void string_unittest_free_char_pp(char **pp, size_t entries) {
for(size_t i = 0; i < entries ;i++)
freez(pp[i]);
freez(pp);
}
static long unittest_string_entries(void) {
long entries = 0;
for(size_t p = 0; p < STRING_PARTITIONS ;p++)
entries += string_base[p].entries;
return entries;
}
#ifdef NETDATA_INTERNAL_CHECKS
static size_t unittest_string_found_deleted_on_search(void) {
size_t entries = 0;
for(size_t p = 0; p < STRING_PARTITIONS ;p++)
entries += string_base[p].found_deleted_on_search;
return entries;
}
static size_t unittest_string_found_available_on_search(void) {
size_t entries = 0;
for(size_t p = 0; p < STRING_PARTITIONS ;p++)
entries += string_base[p].found_available_on_search;
return entries;
}
static size_t unittest_string_found_deleted_on_insert(void) {
size_t entries = 0;
for(size_t p = 0; p < STRING_PARTITIONS ;p++)
entries += string_base[p].found_deleted_on_insert;
return entries;
}
static size_t unittest_string_found_available_on_insert(void) {
size_t entries = 0;
for(size_t p = 0; p < STRING_PARTITIONS ;p++)
entries += string_base[p].found_available_on_insert;
return entries;
}
static size_t unittest_string_spins(void) {
size_t entries = 0;
for(size_t p = 0; p < STRING_PARTITIONS ;p++)
entries += string_base[p].spins;
return entries;
}
#endif // NETDATA_INTERNAL_CHECKS
int string_unittest(size_t entries) {
size_t errors = 0;
fprintf(stderr, "Generating %zu names and values...\n", entries);
char **names = string_unittest_generate_names(entries);
// check string
{
long entries_starting = unittest_string_entries();
fprintf(stderr, "\nChecking strings...\n");
STRING *s1 = string_strdupz("hello unittest");
STRING *s2 = string_strdupz("hello unittest");
if(s1 != s2) {
errors++;
fprintf(stderr, "ERROR: duplicating strings are not deduplicated\n");
}
else
fprintf(stderr, "OK: duplicating string are deduplicated\n");
STRING *s3 = string_dup(s1);
if(s3 != s1) {
errors++;
fprintf(stderr, "ERROR: cloning strings are not deduplicated\n");
}
else
fprintf(stderr, "OK: cloning string are deduplicated\n");
if(s1->refcount != 3) {
errors++;
fprintf(stderr, "ERROR: string refcount is not 3\n");
}
else
fprintf(stderr, "OK: string refcount is 3\n");
STRING *s4 = string_strdupz("world unittest");
if(s4 == s1) {
errors++;
fprintf(stderr, "ERROR: string is sharing pointers on different strings\n");
}
else
fprintf(stderr, "OK: string is properly handling different strings\n");
usec_t start_ut, end_ut;
STRING **strings = mallocz(entries * sizeof(STRING *));
start_ut = now_realtime_usec();
for(size_t i = 0; i < entries ;i++) {
strings[i] = string_strdupz(names[i]);
}
end_ut = now_realtime_usec();
fprintf(stderr, "Created %zu strings in %"PRIu64" usecs\n", entries, end_ut - start_ut);
start_ut = now_realtime_usec();
for(size_t i = 0; i < entries ;i++) {
strings[i] = string_dup(strings[i]);
}
end_ut = now_realtime_usec();
fprintf(stderr, "Cloned %zu strings in %"PRIu64" usecs\n", entries, end_ut - start_ut);
start_ut = now_realtime_usec();
for(size_t i = 0; i < entries ;i++) {
strings[i] = string_strdupz(string2str(strings[i]));
}
end_ut = now_realtime_usec();
fprintf(stderr, "Found %zu existing strings in %"PRIu64" usecs\n", entries, end_ut - start_ut);
start_ut = now_realtime_usec();
for(size_t i = 0; i < entries ;i++) {
string_freez(strings[i]);
}
end_ut = now_realtime_usec();
fprintf(stderr, "Released %zu referenced strings in %"PRIu64" usecs\n", entries, end_ut - start_ut);
start_ut = now_realtime_usec();
for(size_t i = 0; i < entries ;i++) {
string_freez(strings[i]);
}
end_ut = now_realtime_usec();
fprintf(stderr, "Released (again) %zu referenced strings in %"PRIu64" usecs\n", entries, end_ut - start_ut);
start_ut = now_realtime_usec();
for(size_t i = 0; i < entries ;i++) {
string_freez(strings[i]);
}
end_ut = now_realtime_usec();
fprintf(stderr, "Freed %zu strings in %"PRIu64" usecs\n", entries, end_ut - start_ut);
freez(strings);
if(unittest_string_entries() != entries_starting + 2) {
errors++;
fprintf(stderr, "ERROR: strings dictionary should have %ld items but it has %ld\n",
entries_starting + 2, unittest_string_entries());
}
else
fprintf(stderr, "OK: strings dictionary has 2 items\n");
}
// check 2-way merge
{
struct testcase {
char *src1; char *src2; char *expected;
} tests[] = {
{ "", "", ""},
{ "a", "", "[x]"},
{ "", "a", "[x]"},
{ "a", "a", "a"},
{ "abcd", "abcd", "abcd"},
{ "foo_cs", "bar_cs", "[x]_cs"},
{ "cp_UNIQUE_INFIX_cs", "cp_unique_infix_cs", "cp_[x]_cs"},
{ "cp_UNIQUE_INFIX_ci_unique_infix_cs", "cp_unique_infix_ci_UNIQUE_INFIX_cs", "cp_[x]_cs"},
{ "foo[1234]", "foo[4321]", "foo[[x]]"},
{ NULL, NULL, NULL },
};
for (struct testcase *tc = &tests[0]; tc->expected != NULL; tc++) {
STRING *src1 = string_strdupz(tc->src1);
STRING *src2 = string_strdupz(tc->src2);
STRING *expected = string_strdupz(tc->expected);
STRING *result = string_2way_merge(src1, src2);
if (string_cmp(result, expected) != 0) {
fprintf(stderr, "string_2way_merge(\"%s\", \"%s\") -> \"%s\" (expected=\"%s\")\n",
string2str(src1),
string2str(src2),
string2str(result),
string2str(expected));
errors++;
}
string_freez(src1);
string_freez(src2);
string_freez(expected);
string_freez(result);
}
}
// threads testing of string
{
struct thread_unittest tu = {
.dups = 1,
.join = 0,
};
#ifdef NETDATA_INTERNAL_CHECKS
size_t ofound_deleted_on_search = unittest_string_found_deleted_on_search(),
ofound_available_on_search = unittest_string_found_available_on_search(),
ofound_deleted_on_insert = unittest_string_found_deleted_on_insert(),
ofound_available_on_insert = unittest_string_found_available_on_insert(),
ospins = unittest_string_spins();
#endif
size_t oinserts, odeletes, osearches, oentries, oreferences, omemory, oduplications, oreleases;
string_statistics(&oinserts, &odeletes, &osearches, &oentries, &oreferences, &omemory, &oduplications, &oreleases);
time_t seconds_to_run = 5;
int threads_to_create = 2;
fprintf(
stderr,
"Checking string concurrency with %d threads for %lld seconds...\n",
threads_to_create,
(long long)seconds_to_run);
// check string concurrency
netdata_thread_t threads[threads_to_create];
tu.join = 0;
for (int i = 0; i < threads_to_create; i++) {
char buf[100 + 1];
snprintf(buf, 100, "string%d", i);
netdata_thread_create(
&threads[i], buf, NETDATA_THREAD_OPTION_DONT_LOG | NETDATA_THREAD_OPTION_JOINABLE, string_thread, &tu);
}
sleep_usec(seconds_to_run * USEC_PER_SEC);
__atomic_store_n(&tu.join, 1, __ATOMIC_RELAXED);
for (int i = 0; i < threads_to_create; i++) {
void *retval;
netdata_thread_join(threads[i], &retval);
}
size_t inserts, deletes, searches, sentries, references, memory, duplications, releases;
string_statistics(&inserts, &deletes, &searches, &sentries, &references, &memory, &duplications, &releases);
fprintf(stderr, "inserts %zu, deletes %zu, searches %zu, entries %zu, references %zu, memory %zu, duplications %zu, releases %zu\n",
inserts - oinserts, deletes - odeletes, searches - osearches, sentries - oentries, references - oreferences, memory - omemory, duplications - oduplications, releases - oreleases);
#ifdef NETDATA_INTERNAL_CHECKS
size_t found_deleted_on_search = unittest_string_found_deleted_on_search(),
found_available_on_search = unittest_string_found_available_on_search(),
found_deleted_on_insert = unittest_string_found_deleted_on_insert(),
found_available_on_insert = unittest_string_found_available_on_insert(),
spins = unittest_string_spins();
fprintf(stderr, "on insert: %zu ok + %zu deleted\non search: %zu ok + %zu deleted\nspins: %zu\n",
found_available_on_insert - ofound_available_on_insert,
found_deleted_on_insert - ofound_deleted_on_insert,
found_available_on_search - ofound_available_on_search,
found_deleted_on_search - ofound_deleted_on_search,
spins - ospins
);
#endif
}
string_unittest_free_char_pp(names, entries);
fprintf(stderr, "\n%zu errors found\n", errors);
return errors ? 1 : 0;
}
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