bool ConcurrentTableSharedStore::store(const String& key, const Variant& value,
int64_t ttl,
bool overwrite /* = true */,
bool limit_ttl /* = true */) {
StoreValue *sval;
APCHandle* svar = construct(value);
ConditionalReadLock l(m_lock, !apcExtension::ConcurrentTableLockFree ||
m_lockingFlag);
const char *kcp = strdup(key.data());
bool present;
time_t expiry = 0;
bool overwritePrime = false;
{
Map::accessor acc;
present = !m_vars.insert(acc, kcp);
sval = &acc->second;
if (present) {
free((void *)kcp);
if (overwrite || sval->expired()) {
// if ApcTTLLimit is set, then only primed keys can have expiry == 0
overwritePrime = (sval->expiry == 0);
if (sval->inMem()) {
sval->var->unreferenceRoot();
} else {
// mark the inFile copy invalid since we are updating the key
sval->sAddr = nullptr;
sval->sSize = 0;
}
} else {
svar->unreferenceRoot();
return false;
}
}
int64_t adjustedTtl = adjust_ttl(ttl, overwritePrime || !limit_ttl);
if (check_noTTL(key.data(), key.size())) {
adjustedTtl = 0;
}
sval->set(svar, adjustedTtl);
expiry = sval->expiry;
}
if (expiry) {
addToExpirationQueue(key.data(), expiry);
}
if (apcExtension::ExpireOnSets) {
purgeExpired();
}
return true;
}
bool ConcurrentTableSharedStore::storeImpl(const String& key,
const Variant& value,
int64_t ttl,
bool overwrite,
bool limit_ttl) {
StoreValue *sval;
auto svar = APCHandle::Create(value, false, APCHandleLevel::Outer, false);
auto keyLen = key.size();
ReadLock l(m_lock);
char* const kcp = strdup(key.data());
bool present;
time_t expiry = 0;
bool overwritePrime = false;
{
Map::accessor acc;
APCHandle* current = nullptr;
present = !m_vars.insert(acc, kcp);
sval = &acc->second;
if (present) {
free(kcp);
if (!overwrite && !sval->expired()) {
svar.handle->unreferenceRoot(svar.size);
return false;
}
sval->data.match(
[&] (APCHandle* handle) {
current = handle;
// If ApcTTLLimit is set, then only primed keys can have
// expire == 0.
overwritePrime = sval->expire == 0;
},
[&] (char*) {
// Was inFile, but won't be anymore.
sval->data = nullptr;
sval->dataSize = 0;
overwritePrime = true;
}
);
} else {
APCStats::getAPCStats().addKey(keyLen);
}
int64_t adjustedTtl = adjust_ttl(ttl, overwritePrime || !limit_ttl);
if (check_noTTL(key.data(), key.size())) {
adjustedTtl = 0;
}
if (current) {
if (sval->expire == 0 && adjustedTtl != 0) {
APCStats::getAPCStats().removeAPCValue(
sval->dataSize, current, true, sval->expired());
APCStats::getAPCStats().addAPCValue(svar.handle, svar.size, false);
} else {
APCStats::getAPCStats().updateAPCValue(
svar.handle, svar.size, current, sval->dataSize,
sval->expire == 0, sval->expired());
}
current->unreferenceRoot(sval->dataSize);
} else {
APCStats::getAPCStats().addAPCValue(svar.handle, svar.size, present);
}
sval->set(svar.handle, adjustedTtl);
sval->dataSize = svar.size;
expiry = sval->expire;
if (expiry) {
auto ikey = intptr_t(acc->first);
if (m_expMap.insert({ ikey, 0 })) {
m_expQueue.push({ ikey, expiry });
}
}
}
if (apcExtension::ExpireOnSets) {
purgeExpired();
}
return true;
}
bool ConcurrentTableSharedStore::store(CStrRef key, CVarRef val, int64 ttl,
bool overwrite /* = true */) {
bool stats = RuntimeOption::EnableStats && RuntimeOption::EnableAPCStats;
bool statsDetail = RuntimeOption::EnableAPCSizeStats &&
RuntimeOption::EnableAPCSizeGroup;
StoreValue *sval;
SharedVariant* var = construct(key, val);
ReadLock l(m_lock);
const char *kcp = strdup(key.data());
bool present;
time_t expiry;
{
Map::accessor acc;
present = !m_vars.insert(acc, kcp);
sval = &acc->second;
if (present) {
free((void *)kcp);
if (overwrite || sval->expired()) {
if (statsDetail) {
SharedStoreStats::onDelete(key.get(), sval->var, true);
}
sval->var->decRef();
if (RuntimeOption::EnableAPCSizeStats && !check_skip(key.data())) {
int32 size = var->getSpaceUsage();
SharedStoreStats::updateDirect(sval->size, size);
sval->size = size;
}
} else {
var->decRef();
return false;
}
} else {
if (RuntimeOption::EnableAPCSizeStats) {
int32 size = var->getSpaceUsage();
SharedStoreStats::addDirect(key.size(), size);
sval->size = size;
}
}
sval->set(var, ttl);
expiry = sval->expiry;
if (statsDetail) {
SharedStoreStats::onStore(key.get(), var, ttl, false);
}
}
if (RuntimeOption::ApcExpireOnSets) {
if (ttl) {
addToExpirationQueue(key.data(), expiry);
}
purgeExpired();
}
if (stats) {
if (present) {
ServerStats::Log("apc.update", 1);
} else {
ServerStats::Log("apc.new", 1);
if (RuntimeOption::EnableStats && RuntimeOption::EnableAPCKeyStats) {
string prefix = "apc.new.";
prefix += GetSkeleton(key);
ServerStats::Log(prefix, 1);
}
}
}
return true;
}
bool ConcurrentTableSharedStore::store(CStrRef key, CVarRef value, int64 ttl,
bool overwrite /* = true */) {
StoreValue *sval;
SharedVariant* svar = construct(value);
ConditionalReadLock l(m_lock, !RuntimeOption::ApcConcurrentTableLockFree ||
m_lockingFlag);
const char *kcp = strdup(key.data());
bool present;
time_t expiry = 0;
bool overwritePrime = false;
{
Map::accessor acc;
present = !m_vars.insert(acc, kcp);
sval = &acc->second;
bool update = false;
if (present) {
free((void *)kcp);
if (overwrite || sval->expired()) {
// if ApcTTLLimit is set, then only primed keys can have expiry == 0
overwritePrime = (sval->expiry == 0);
if (sval->inMem()) {
stats_on_update(key.get(), sval, svar,
adjust_ttl(ttl, overwritePrime));
sval->var->decRef();
update = true;
} else {
// mark the inFile copy invalid since we are updating the key
sval->sAddr = NULL;
sval->sSize = 0;
}
} else {
svar->decRef();
return false;
}
}
int64 adjustedTtl = adjust_ttl(ttl, overwritePrime);
if (check_noTTL(key.data())) {
adjustedTtl = 0;
}
sval->set(svar, adjustedTtl);
expiry = sval->expiry;
if (!update) {
stats_on_add(key.get(), sval, adjustedTtl, false, false);
}
}
if (expiry) {
addToExpirationQueue(key.data(), expiry);
}
if (RuntimeOption::ApcExpireOnSets) {
purgeExpired();
}
if (present) {
log_apc(std_apc_update);
} else {
log_apc(std_apc_new);
if (RuntimeOption::EnableStats && RuntimeOption::EnableAPCKeyStats) {
string prefix = "apc.new." + GetSkeleton(key);
ServerStats::Log(prefix, 1);
}
}
return true;
}
