lokinet/llarp/util/metrics_core.hpp

1336 lines
33 KiB
C++
Raw Normal View History

2019-02-27 21:46:23 +00:00
#ifndef LLARP_METRICS_CORE_HPP
#define LLARP_METRICS_CORE_HPP
#include <util/metrics_types.hpp>
#include <util/scheduler.hpp>
#include <util/stopwatch.hpp>
#include <util/threading.hpp>
#include <map>
#include <memory>
#include <vector>
namespace llarp
{
namespace metrics
{
class IntCollector
{
const Id m_id;
size_t m_count GUARDED_BY(m_mutex);
int64_t m_total GUARDED_BY(m_mutex);
int m_min GUARDED_BY(m_mutex);
int m_max GUARDED_BY(m_mutex);
mutable util::Mutex m_mutex;
IntCollector(const IntCollector &) = delete;
IntCollector &
operator=(const IntCollector &) = delete;
public:
static constexpr int DEFAULT_MIN = std::numeric_limits< int >::max();
static constexpr int DEFAULT_MAX = std::numeric_limits< int >::min();
IntCollector(const Id &id)
: m_id(id)
, m_count(0)
, m_total(0)
, m_min(DEFAULT_MIN)
, m_max(DEFAULT_MAX)
{
}
const Id &
id() const
{
return m_id;
}
void
clear()
{
absl::WriterMutexLock l(&m_mutex);
m_count = 0;
m_total = 0;
m_min = DEFAULT_MIN;
m_max = DEFAULT_MAX;
}
Record
loadAndClear();
Record
load();
void
tick(int value)
{
absl::WriterMutexLock l(&m_mutex);
m_count++;
m_total += value;
m_min = std::min(m_min, value);
m_max = std::max(m_max, value);
}
void
accumulate(size_t count, int total, int min, int max)
{
absl::WriterMutexLock l(&m_mutex);
m_count += count;
m_total += total;
m_min = std::min(m_min, min);
m_max = std::max(m_max, max);
}
void
set(size_t count, int total, int min, int max)
{
absl::WriterMutexLock l(&m_mutex);
m_count = count;
m_total = total;
m_min = min;
m_max = max;
}
};
class DoubleCollector
{
Record m_record GUARDED_BY(m_mutex);
mutable util::Mutex m_mutex;
DoubleCollector(const DoubleCollector &) = delete;
DoubleCollector &
operator=(const DoubleCollector &) = delete;
public:
DoubleCollector(const Id &id) : m_record(id)
{
}
void
clear()
{
absl::WriterMutexLock l(&m_mutex);
m_record.count() = 0;
m_record.total() = 0.0;
m_record.min() = Record::DEFAULT_MIN;
m_record.max() = Record::DEFAULT_MAX;
}
Record
loadAndClear()
{
absl::WriterMutexLock l(&m_mutex);
Record rec = m_record;
m_record.count() = 0;
m_record.total() = 0.0;
m_record.min() = Record::DEFAULT_MIN;
m_record.max() = Record::DEFAULT_MAX;
return rec;
}
Record
load()
{
absl::ReaderMutexLock l(&m_mutex);
return m_record;
}
void
tick(double value)
{
absl::WriterMutexLock l(&m_mutex);
m_record.count()++;
m_record.total() += value;
m_record.min() = std::min(m_record.min(), value);
m_record.max() = std::max(m_record.max(), value);
}
void
accumulate(size_t count, double total, double min, double max)
{
absl::WriterMutexLock l(&m_mutex);
m_record.count() += count;
m_record.total() += total;
m_record.min() = std::min(m_record.min(), min);
m_record.max() = std::max(m_record.max(), max);
}
void
set(size_t count, double total, double min, double max)
{
absl::WriterMutexLock l(&m_mutex);
m_record.count() = count;
m_record.total() = total;
m_record.min() = min;
m_record.max() = max;
}
const Id &
id() const
{
absl::ReaderMutexLock l(&m_mutex);
return m_record.id();
}
};
class Publisher
{
public:
virtual ~Publisher() = 0;
virtual void
publish(const Sample &sample) = 0;
};
inline Publisher::~Publisher()
{
}
static inline void
combine(Record &record, const Record &toAdd)
{
record.id() = toAdd.id();
record.count() += toAdd.count();
record.total() += toAdd.total();
record.min() = std::min(record.min(), toAdd.min());
record.max() = std::max(record.max(), toAdd.max());
}
template < typename Collector >
class Collectors
{
using CollectorPtr = std::shared_ptr< Collector >;
using CollectorSet = std::set< CollectorPtr >;
Collector m_default;
CollectorSet m_collectors;
Collectors(const Collectors &) = delete;
Collectors &
operator=(const Collectors &) = delete;
public:
Collectors(const Id &id) : m_default(id)
{
}
Collector *
defaultCollector()
{
return &m_default;
}
std::shared_ptr< Collector >
add()
{
auto ptr = std::make_shared< Collector >(m_default.id());
m_collectors.insert(ptr);
return ptr;
}
bool
remove(Collector *collector)
{
std::shared_ptr< Collector > ptr(collector, [](Collector *) {});
size_t count = m_collectors.erase(ptr);
return count > 0;
}
Record
combineAndClear()
{
Record rec = m_default.loadAndClear();
for(auto &ptr : m_collectors)
{
metrics::combine(rec, ptr->loadAndClear());
}
return rec;
}
Record
combine()
{
Record rec = m_default.load();
for(auto &ptr : m_collectors)
{
metrics::combine(rec, ptr->load());
}
return rec;
}
std::vector< std::shared_ptr< Collector > >
collectors() const
{
return std::vector< std::shared_ptr< Collector > >(m_collectors.begin(),
m_collectors.end());
}
const Id &
id() const
{
return m_default.id();
}
};
class MetricCollectors
{
using DoubleCollectors = Collectors< DoubleCollector >;
using IntCollectors = Collectors< IntCollector >;
DoubleCollectors m_doubleCollectors;
IntCollectors m_intCollectors;
MetricCollectors(const MetricCollectors &) = delete;
MetricCollectors &
operator=(const MetricCollectors &) = delete;
public:
MetricCollectors(const Id &id)
: m_doubleCollectors(id), m_intCollectors(id)
{
}
Collectors< DoubleCollector > &
doubleCollectors()
{
return m_doubleCollectors;
}
Collectors< IntCollector > &
intCollectors()
{
return m_intCollectors;
}
const Collectors< DoubleCollector > &
doubleCollectors() const
{
return m_doubleCollectors;
}
const Collectors< IntCollector > &
intCollectors() const
{
return m_intCollectors;
}
Record
combineAndClear()
{
Record res = m_doubleCollectors.combineAndClear();
metrics::combine(res, m_intCollectors.combineAndClear());
return res;
}
Record
combine()
{
Record res = m_doubleCollectors.combine();
metrics::combine(res, m_intCollectors.combine());
return res;
}
const Id &
id() const
{
return m_intCollectors.id();
}
};
class Registry
{
using NamedCategory = std::tuple< const char *, const char * >;
struct CmpNamedCategory
{
bool
operator()(const NamedCategory &lhs, const NamedCategory &rhs) const
{
int ret = std::strcmp(std::get< 0 >(lhs), std::get< 0 >(rhs));
if(ret == 0)
{
ret = std::strcmp(std::get< 1 >(lhs), std::get< 1 >(rhs));
}
return ret < 0;
}
};
struct StrCmp
{
bool
operator()(const char *lhs, const char *rhs) const
{
return std::strcmp(lhs, rhs) < 0;
}
};
using MetricMap = std::map< NamedCategory, std::shared_ptr< Description >,
CmpNamedCategory >;
using CategoryMap =
std::map< const char *, std::shared_ptr< Category >, StrCmp >;
std::set< std::string > m_stringmem GUARDED_BY(m_mutex);
CategoryMap m_categories GUARDED_BY(m_mutex);
MetricMap m_metrics GUARDED_BY(m_mutex);
bool m_defaultEnabled GUARDED_BY(m_mutex);
mutable util::Mutex m_mutex;
Registry(const Registry &) = delete;
Registry &
operator=(const Registry &) = delete;
std::tuple< Id, bool >
insert(const char *category, const char *name)
EXCLUSIVE_LOCKS_REQUIRED(m_mutex);
public:
Registry() : m_defaultEnabled(true)
{
}
Id
add(const char *category, const char *name) LOCKS_EXCLUDED(m_mutex);
Id
get(const char *category, const char *name) LOCKS_EXCLUDED(m_mutex);
const Category *
add(const char *category) LOCKS_EXCLUDED(m_mutex);
const Category *
get(const char *category);
void
enable(const Category *category, bool value);
void
enableAll(bool value);
void
registerContainer(const Category *category, CategoryContainer &container);
void
publicationType(const Id &id, Publication::Type type);
void
setFormat(const Id &id, const Format &format);
size_t
metricCount() const
{
absl::ReaderMutexLock l(&m_mutex);
return m_metrics.size();
}
size_t
categoryCount() const
{
absl::ReaderMutexLock l(&m_mutex);
return m_categories.size();
}
const Category *
findCategory(const char *category) const;
Id
findId(const char *category, const char *name) const;
std::vector< const Category * >
getAll() const;
};
class CollectorRepo
{
using MetricCollectorsPtr = std::shared_ptr< MetricCollectors >;
using IdCollectors = std::map< Id, MetricCollectorsPtr >;
using CategoryCollectors =
std::map< const Category *, std::vector< MetricCollectors * > >;
Registry *m_registry;
IdCollectors m_collectors;
CategoryCollectors m_categories;
mutable util::Mutex m_mutex;
CollectorRepo(const CollectorRepo &) = delete;
CollectorRepo &
operator=(const CollectorRepo &) = delete;
MetricCollectors &
getCollectors(const Id &id);
public:
CollectorRepo(Registry *registry) : m_registry(registry)
{
}
std::vector< Record >
collectAndClear(const Category *category);
std::vector< Record >
collect(const Category *category);
DoubleCollector *
defaultDoubleCollector(const char *category, const char *name)
{
return defaultDoubleCollector(m_registry->get(category, name));
}
DoubleCollector *
defaultDoubleCollector(const Id &id);
IntCollector *
defaultIntCollector(const char *category, const char *name)
{
return defaultIntCollector(m_registry->get(category, name));
}
IntCollector *
defaultIntCollector(const Id &id);
std::shared_ptr< DoubleCollector >
addDoubleCollector(const char *category, const char *name)
{
return addDoubleCollector(m_registry->get(category, name));
}
std::shared_ptr< DoubleCollector >
addDoubleCollector(const Id &id)
{
absl::WriterMutexLock l(&m_mutex);
return getCollectors(id).doubleCollectors().add();
}
std::shared_ptr< IntCollector >
addIntCollector(const char *category, const char *name)
{
return addIntCollector(m_registry->get(category, name));
}
std::shared_ptr< IntCollector >
addIntCollector(const Id &id)
{
absl::WriterMutexLock l(&m_mutex);
return getCollectors(id).intCollectors().add();
}
std::pair< std::vector< std::shared_ptr< DoubleCollector > >,
std::vector< std::shared_ptr< IntCollector > > >
allCollectors(const Id &id);
Registry &
registry()
{
return *m_registry;
}
const Registry &
registry() const
{
return *m_registry;
}
};
class Manager;
class PublisherRegistry
{
using PubPtr = std::shared_ptr< Publisher >;
using CatPublishers = std::multimap< const Category *, PubPtr >;
using PubSet = std::set< PubPtr >;
using PubReg = std::map< const Category *, CatPublishers::iterator >;
using RegInfo = std::map< PubPtr, PubReg >;
CatPublishers m_categoryPublishers;
RegInfo m_registry;
PubSet m_publishers;
PublisherRegistry(const PublisherRegistry &) = delete;
PublisherRegistry &
operator=(const PublisherRegistry &) = delete;
public:
using GlobalIterator = PubSet::iterator;
using CatIterator = CatPublishers::iterator;
PublisherRegistry() = default;
bool
addGlobalPublisher(const std::shared_ptr< Publisher > &publisher)
{
if(m_publishers.find(publisher) != m_publishers.end())
{
return false;
}
if(m_registry.find(publisher) != m_registry.end())
{
return false;
}
m_publishers.insert(publisher);
return true;
}
bool
addPublisher(const Category *category,
const std::shared_ptr< Publisher > &publisher)
{
if(m_publishers.find(publisher) != m_publishers.end())
{
return false;
}
auto &reg = m_registry[publisher];
if(reg.find(category) != reg.end())
{
return false;
}
auto it = m_categoryPublishers.emplace(category, publisher);
reg.emplace(category, it);
return true;
}
bool
removePublisher(const Publisher *publisher)
{
std::shared_ptr< Publisher > ptr(const_cast< Publisher * >(publisher),
[](Publisher *) {});
auto allIt = m_publishers.find(ptr);
if(allIt != m_publishers.end())
{
m_publishers.erase(allIt);
return true;
}
auto regIt = m_registry.find(ptr);
if(regIt == m_registry.end())
{
return false;
}
for(auto &spec : regIt->second)
{
m_categoryPublishers.erase(spec.second);
}
m_registry.erase(regIt);
return true;
}
GlobalIterator
globalBegin()
{
return m_publishers.begin();
}
GlobalIterator
globalEnd()
{
return m_publishers.end();
}
CatIterator
catBegin()
{
return m_categoryPublishers.begin();
}
CatIterator
catEnd()
{
return m_categoryPublishers.end();
}
CatIterator
lowerBound(const Category *category)
{
return m_categoryPublishers.lower_bound(category);
}
CatIterator
upperBound(const Category *category)
{
return m_categoryPublishers.upper_bound(category);
}
std::vector< Publisher * >
globalPublishers() const
{
std::vector< Publisher * > result;
result.reserve(m_publishers.size());
std::transform(m_publishers.begin(), m_publishers.end(),
std::back_inserter(result),
[](const auto &p) { return p.get(); });
return result;
}
std::vector< Publisher * >
catPublishers(const Category *category) const
{
std::vector< Publisher * > result;
auto beg = m_categoryPublishers.lower_bound(category);
auto end = m_categoryPublishers.upper_bound(category);
result.reserve(std::distance(beg, end));
std::transform(beg, end, std::back_inserter(result),
[](const auto &p) { return p.second.get(); });
return result;
}
};
class CallbackRegistry
{
using Handle = uint64_t;
using RecordCallback = std::function< std::vector< Record >(bool) >;
using CallbackMap = std::multimap< const Category *, RecordCallback >;
using HandleMap = std::map< Handle, CallbackMap::iterator >;
Handle m_next;
CallbackMap m_callbackMap;
HandleMap m_handleMap;
CallbackRegistry(const CallbackRegistry &) = delete;
CallbackRegistry &
operator=(const CallbackRegistry &) = delete;
public:
using iterator = CallbackMap::iterator;
CallbackRegistry() : m_next(1)
{
}
Handle
registerCallback(const Category *category, const RecordCallback &callback)
{
Handle handle = m_next++;
auto it = m_callbackMap.emplace(category, callback);
m_handleMap.emplace(handle, it);
return handle;
}
bool
removeCallback(Handle handle)
{
auto it = m_handleMap.find(handle);
if(it == m_handleMap.end())
{
return false;
}
m_callbackMap.erase(it->second);
m_handleMap.erase(it);
return true;
}
iterator
begin()
{
return m_callbackMap.begin();
}
iterator
end()
{
return m_callbackMap.end();
}
iterator
lowerBound(const Category *category)
{
return m_callbackMap.lower_bound(category);
}
iterator
upperBound(const Category *category)
{
return m_callbackMap.upper_bound(category);
}
std::vector< const RecordCallback * >
callbacksFor(const Category *category) const
{
std::vector< const RecordCallback * > result;
auto beg = m_callbackMap.lower_bound(category);
auto end = m_callbackMap.upper_bound(category);
result.reserve(std::distance(beg, end));
std::transform(beg, end, std::back_inserter(result),
[](const auto &x) { return &x.second; });
return result;
}
};
struct PublisherHelper;
/// The big dog.
/// This class owns everything else, and is responsible for managing the
/// gathering and publishing of metrics
class Manager
{
public:
// Public callback. If the bool flag is true, clear the metrics back to
// their default state.
using RecordCallback = std::function< std::vector< Record >(bool) >;
using Handle = uint64_t;
private:
// Map categories to the times they were last reset
using ResetTimes = std::map< const Category *, absl::Duration >;
friend struct PublisherHelper;
Registry m_registry;
CollectorRepo m_repo;
CallbackRegistry m_callbacks GUARDED_BY(m_mutex);
PublisherRegistry m_publishers GUARDED_BY(m_mutex);
const absl::Duration m_createTime;
ResetTimes m_resetTimes;
util::Mutex m_publishLock ACQUIRED_BEFORE(m_mutex);
mutable util::Mutex m_mutex ACQUIRED_AFTER(m_publishLock);
public:
static constexpr Handle INVALID_HANDLE =
std::numeric_limits< Handle >::max();
Manager()
: m_repo(&m_registry), m_createTime(absl::Now() - absl::UnixEpoch())
{
}
/// Register a callback for
Handle
registerCallback(const char *categoryName, const RecordCallback &callback)
{
return registerCallback(m_registry.get(categoryName), callback);
}
Handle
registerCallback(const Category *category, const RecordCallback &callback)
{
absl::WriterMutexLock l(&m_mutex);
return m_callbacks.registerCallback(category, callback);
}
bool
removeCallback(Handle handle)
{
absl::WriterMutexLock l(&m_mutex);
return m_callbacks.removeCallback(handle);
}
/// Add a `publisher` which will receive all events
bool
addGlobalPublisher(const std::shared_ptr< Publisher > &publisher)
{
absl::WriterMutexLock l(&m_mutex);
return m_publishers.addGlobalPublisher(publisher);
}
/// Add a `publisher` which will receive events for the given
/// `categoryName` only
bool
addPublisher(const char *categoryName,
const std::shared_ptr< Publisher > &publisher)
{
return addPublisher(m_registry.get(categoryName), publisher);
}
/// Add a `publisher` which will receive events for the given
/// `category` only
bool
addPublisher(const Category *category,
const std::shared_ptr< Publisher > &publisher)
{
absl::WriterMutexLock l(&m_mutex);
return m_publishers.addPublisher(category, publisher);
}
bool
removePublisher(const Publisher *publisher)
{
absl::WriterMutexLock l(&m_mutex);
return m_publishers.removePublisher(publisher);
}
bool
removePublisher(const std::shared_ptr< Publisher > &publisher)
{
absl::WriterMutexLock l(&m_mutex);
return m_publishers.removePublisher(publisher.get());
}
// clang-format off
CollectorRepo& collectorRepo() { return m_repo; }
const CollectorRepo& collectorRepo() const { return m_repo; }
Registry& registry() { return m_registry; }
const Registry& registry() const { return m_registry; }
// clang-format on
/// Publish specific categories of metric matching the category/categories
Sample
collectSample(std::vector< Record > &records, bool clear = false)
{
std::vector< const Category * > allCategories = m_registry.getAll();
return collectSample(
records, absl::Span< const Category * >{allCategories}, clear);
}
Sample
collectSample(std::vector< Record > &records,
absl::Span< const Category * > categories,
bool clear = false);
/// Publish specific categories of metric matching the category/categories
void
publish(const Category *category, bool clear = true)
{
publish(absl::Span< const Category * >(&category, 1), clear);
}
void
publish(absl::Span< const Category * > categories, bool clear = true);
void
publish(const std::set< const Category * > &categories,
bool clear = true);
void
publishAll(bool clear = true)
{
std::vector< const Category * > allCategories = m_registry.getAll();
publish(absl::Span< const Category * >{allCategories}, clear);
}
void
publishAllExcluding(const std::set< const Category * > &excludeCategories,
bool clear = true)
{
if(excludeCategories.empty())
{
publishAll(clear);
return;
}
std::vector< const Category * > allCategories = m_registry.getAll();
std::vector< const Category * > includedCategories;
includedCategories.reserve(allCategories.size()
- excludeCategories.size());
std::copy_if(
allCategories.begin(), allCategories.end(),
std::back_inserter(includedCategories), [&](const Category *cat) {
return excludeCategories.end() == excludeCategories.find(cat);
});
if(!includedCategories.empty())
{
publish(absl::Span< const Category * >{includedCategories}, clear);
}
}
void
enableCategory(const char *categoryName, bool enable = true)
{
m_registry.enable(m_registry.get(categoryName), enable);
}
void
enableCategory(const Category *category, bool enable = true)
{
m_registry.enable(category, enable);
}
void
enableAll(bool enable)
{
m_registry.enableAll(enable);
}
std::vector< Publisher * >
globalPublishers() const
{
absl::ReaderMutexLock l(&m_mutex);
return m_publishers.globalPublishers();
}
std::vector< Publisher * >
publishersForCategory(const char *categoryName) const
{
const Category *category = m_registry.findCategory(categoryName);
return category ? publishersForCategory(category)
: std::vector< Publisher * >();
}
std::vector< Publisher * >
publishersForCategory(const Category *category) const
{
absl::ReaderMutexLock l(&m_mutex);
return m_publishers.catPublishers(category);
}
};
/// Provide a handy mechanism for retrieving the default manager, without
/// a painful singleton mechanism
class DefaultManager
{
static Manager *m_manager;
public:
static Manager *
instance()
{
return m_manager;
}
static Manager *
manager(Manager *value)
{
return value ? value : m_manager;
}
static Manager *
create()
{
m_manager = new Manager;
return m_manager;
}
static void
destroy()
{
delete m_manager;
m_manager = nullptr;
}
};
/// Scoped guard to manage the default manager
class DefaultManagerGuard
{
DefaultManagerGuard(const DefaultManagerGuard &) = delete;
DefaultManagerGuard &
operator=(const DefaultManagerGuard &) = delete;
public:
DefaultManagerGuard()
{
DefaultManager::create();
}
~DefaultManagerGuard()
{
DefaultManager::destroy();
}
Manager *
instance()
{
return DefaultManager::instance();
}
};
template < typename Collector, typename Value,
Collector *(CollectorRepo::*catFunc)(const char *, const char *),
Collector *(CollectorRepo::*idFunc)(const Id &) >
class Metric
{
Collector *m_collector; // can be null
const std::atomic_bool *m_enabled;
public:
static Collector *
lookup(const char *category, const char *name, Manager *manager = nullptr)
{
manager = DefaultManager::manager(manager);
return manager ? (manager->collectorRepo().*catFunc)(category, name)
: 0;
}
static Collector *
lookup(const Id &id, Manager *manager = nullptr)
{
manager = DefaultManager::manager(manager);
return manager ? (manager->collectorRepo().*idFunc)(id) : 0;
}
Metric(const char *category, const char *name, Manager *manager)
: m_collector(lookup(category, name, manager))
, m_enabled(m_collector ? &m_collector->id().category()->enabledRaw()
: nullptr)
{
}
Metric(const Id &id, Manager *manager)
: m_collector(lookup(id, manager))
, m_enabled(m_collector ? &m_collector->id().category()->enabledRaw()
: nullptr)
{
}
Metric(Collector *collector)
: m_collector(collector)
, m_enabled(m_collector ? &m_collector->id().category()->enabledRaw()
: nullptr)
{
}
bool
active() const
{
return m_enabled ? m_enabled->load(std::memory_order_relaxed) : false;
}
void
tick()
{
if(active())
{
m_collector->tick(static_cast< Value >(1));
}
}
void
update(Value val)
{
if(active())
{
m_collector->tick(val);
}
}
void
accumulate(size_t count, Value total, Value min, Value max)
{
if(active())
{
m_collector->accumulate(count, total, min, max);
}
}
void
set(size_t count, Value total, Value min, Value max)
{
if(active())
{
m_collector->set(count, total, min, max);
}
}
Id
id() const
{
return m_collector ? m_collector->id() : Id();
}
const Collector *
collector() const
{
return m_collector;
}
Collector *
collector()
{
return m_collector;
}
static void
getCollector(Collector **collector, CategoryContainer *container,
const char *category, const char *metric)
{
Manager *manager = DefaultManager::instance();
*collector = manager->collectorRepo().*catFunc(category, metric);
manager->registry().registerContainer((*collector)->id().category(),
container);
}
static void
getCollector(Collector **collector, CategoryContainer *container,
const char *category, const char *metric,
Publication::Type type)
{
Manager *manager = DefaultManager::instance();
*collector = manager->collectorRepo().*catFunc(category, metric);
manager->registry().registerContainer((*collector)->id().category(),
container);
manager->registry().publicationType((*collector)->id(), type);
}
};
using DoubleMetric =
Metric< DoubleCollector, double, &CollectorRepo::defaultDoubleCollector,
&CollectorRepo::defaultDoubleCollector >;
using IntMetric =
Metric< IntCollector, int, &CollectorRepo::defaultIntCollector,
&CollectorRepo::defaultIntCollector >;
class TimerGuard
{
private:
util::Stopwatch m_stopwatch;
DoubleCollector *m_collector;
TimerGuard(const TimerGuard &) = delete;
TimerGuard &
operator=(const TimerGuard &) = delete;
public:
TimerGuard(DoubleMetric *metric)
: m_stopwatch()
, m_collector(metric->active() ? metric->collector() : nullptr)
{
if(m_collector)
{
m_stopwatch.start();
}
}
TimerGuard(DoubleCollector *collector)
: m_stopwatch()
, m_collector(collector && collector->id().category()->enabled()
? collector
: nullptr)
{
if(m_collector)
{
m_stopwatch.start();
}
}
TimerGuard(const char *category, const char *name, Manager *manager)
: m_stopwatch(), m_collector(nullptr)
{
DoubleCollector *collector =
DoubleMetric::lookup(category, name, manager);
m_collector = (collector && collector->id().category()->enabled())
? collector
: nullptr;
if(m_collector)
{
m_stopwatch.start();
}
}
TimerGuard(const Id &id, Manager *manager)
: m_stopwatch(), m_collector(nullptr)
{
DoubleCollector *collector = DoubleMetric::lookup(id, manager);
m_collector = (collector && collector->id().category()->enabled())
? collector
: nullptr;
if(m_collector)
{
m_stopwatch.start();
}
}
~TimerGuard()
{
if(active())
{
m_stopwatch.stop();
m_collector->tick(absl::ToDoubleSeconds(m_stopwatch.time()));
}
}
bool
active() const
{
return m_collector ? m_collector->id().category()->enabled() : false;
}
};
struct PublisherSchedulerData;
class PublisherScheduler
{
friend class PublisherSchedulerGuard;
using Categories = std::map< const Category *, absl::Duration >;
using Repeaters =
std::map< absl::Duration, std::shared_ptr< PublisherSchedulerData > >;
thread::Scheduler &m_scheduler;
Manager *m_manager;
Categories m_categories GUARDED_BY(m_mutex);
Repeaters m_repeaters GUARDED_BY(m_mutex);
absl::Duration m_defaultInterval GUARDED_BY(m_mutex);
mutable util::Mutex m_mutex;
void
publish(const std::shared_ptr< PublisherSchedulerData > &data) const;
void
cancel(Categories::iterator it) EXCLUSIVE_LOCKS_REQUIRED(m_mutex);
bool
cancelDefault() EXCLUSIVE_LOCKS_REQUIRED(m_mutex);
public:
PublisherScheduler(thread::Scheduler &scheduler, Manager *manager)
: m_scheduler(scheduler), m_manager(manager), m_defaultInterval()
{
}
~PublisherScheduler()
{
cancelAll();
}
void
schedule(const char *categoryName, absl::Duration interval)
{
return schedule(m_manager->registry().get(categoryName), interval);
}
void
schedule(const Category *category, absl::Duration interval);
void
setDefault(absl::Duration interval);
bool
cancel(const char *categoryName)
{
return cancel(m_manager->registry().get(categoryName));
}
bool
cancel(const Category *category);
bool
clearDefault();
void
cancelAll();
Manager *
manager()
{
return m_manager;
}
const Manager *
manager() const
{
return m_manager;
}
absl::optional< absl::Duration >
find(const char *categoryName) const
{
return find(m_manager->registry().get(categoryName));
}
absl::optional< absl::Duration >
find(const Category *category) const;
absl::optional< absl::Duration >
getDefault() const;
std::vector< std::pair< const Category *, absl::Duration > >
getAll() const;
};
} // namespace metrics
} // namespace llarp
#endif