foundationdb/fdbrpc/Stats.h

265 lines
7.7 KiB
C++

/*
* Stats.h
*
* This source file is part of the FoundationDB open source project
*
* Copyright 2013-2018 Apple Inc. and the FoundationDB project authors
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef FDBRPC_STATS_H
#define FDBRPC_STATS_H
#include <type_traits>
#pragma once
// Yet another performance statistics interface
/*
struct MyCounters {
CounterCollection cc;
Counter foo, bar, baz;
MyCounters() : foo("foo", cc), bar("bar", cc), baz("baz", cc) {}
};
*/
#include <cstdint>
#include <cstddef>
#include "flow/flow.h"
#include "flow/TDMetric.actor.h"
#include "fdbrpc/ContinuousSample.h"
struct ICounter {
// All counters have a name and value
virtual std::string const& getName() const = 0;
virtual int64_t getValue() const = 0;
// Counters may also have rate and roughness
virtual bool hasRate() const = 0;
virtual double getRate() const = 0;
virtual bool hasRoughness() const = 0;
virtual double getRoughness() const = 0;
virtual void resetInterval() = 0;
virtual void remove() {}
};
template <>
struct Traceable<ICounter*> : std::true_type {
static std::string toString(ICounter const* counter) {
if (counter->hasRate() && counter->hasRoughness()) {
return format("%g %g %lld", counter->getRate(), counter->getRoughness(), (long long)counter->getValue());
} else {
return format("%lld", (long long)counter->getValue());
}
}
};
struct CounterCollection {
CounterCollection(std::string name, std::string id = std::string()) : name(name), id(id) {}
std::vector<struct ICounter*> counters, counters_to_remove;
~CounterCollection() {
for (auto c : counters_to_remove)
c->remove();
}
std::string name;
std::string id;
void logToTraceEvent(TraceEvent& te) const;
};
struct Counter : ICounter, NonCopyable {
public:
typedef int64_t Value;
Counter(std::string const& name, CounterCollection& collection);
void operator+=(Value delta);
void operator++() { *this += 1; }
void clear();
void resetInterval() override;
std::string const& getName() const override { return name; }
Value getIntervalDelta() const { return interval_delta; }
Value getValue() const override { return interval_start_value + interval_delta; }
// dValue / dt
double getRate() const override;
// Measures the clumpiness or dispersion of the counter.
// Computed as a normalized variance of the time between each incrementation of the value.
// A delta of N is treated as N distinct increments, with N-1 increments having time span 0.
// Normalization is performed by dividing each time sample by the mean time before taking variance.
//
// roughness = Variance(t/mean(T)) for time interval samples t in T
//
// A uniformly periodic counter will have roughness of 0
// A uniformly periodic counter that increases in clumps of N will have roughness of N-1
// A counter with exponentially distributed incrementations will have roughness of 1
double getRoughness() const override;
bool hasRate() const override { return true; }
bool hasRoughness() const override { return true; }
private:
std::string name;
double interval_start, last_event, interval_sq_time, roughness_interval_start;
Value interval_delta, interval_start_value;
Int64MetricHandle metric;
};
template <>
struct Traceable<Counter> : std::true_type {
static std::string toString(Counter const& counter) {
return Traceable<ICounter*>::toString((ICounter const*)&counter);
}
};
template <class F>
struct SpecialCounter final : ICounter, FastAllocated<SpecialCounter<F>>, NonCopyable {
SpecialCounter(CounterCollection& collection, std::string const& name, F&& f) : name(name), f(f) {
collection.counters.push_back(this);
collection.counters_to_remove.push_back(this);
}
void remove() override { delete this; }
std::string const& getName() const override { return name; }
int64_t getValue() const override {
auto result = f();
// Disallow conversion from floating point to int64_t, since this has
// been a source of confusion - e.g. a percentage represented as a
// fraction between 0 and 1 is not meaningful after conversion to
// int64_t.
static_assert(!std::is_floating_point_v<decltype(result)>);
return result;
}
void resetInterval() override {}
bool hasRate() const override { return false; }
double getRate() const override { throw internal_error(); }
bool hasRoughness() const override { return false; }
double getRoughness() const override { throw internal_error(); }
std::string name;
F f;
};
template <class F>
static void specialCounter(CounterCollection& collection, std::string const& name, F&& f) {
new SpecialCounter<F>(collection, name, std::move(f));
}
Future<Void> traceCounters(
std::string const& traceEventName,
UID const& traceEventID,
double const& interval,
CounterCollection* const& counters,
std::string const& trackLatestName = std::string(),
std::function<void(TraceEvent&)> const& decorator = [](TraceEvent& te) {});
class LatencyBands {
public:
LatencyBands(std::string name, UID id, double loggingInterval)
: name(name), id(id), loggingInterval(loggingInterval) {}
void addThreshold(double value) {
if (value > 0 && bands.count(value) == 0) {
if (bands.size() == 0) {
ASSERT(!cc && !filteredCount);
cc = std::make_unique<CounterCollection>(name, id.toString());
logger = traceCounters(name, id, loggingInterval, cc.get(), id.toString() + "/" + name);
filteredCount = std::make_unique<Counter>("Filtered", *cc);
insertBand(std::numeric_limits<double>::infinity());
}
insertBand(value);
}
}
void addMeasurement(double measurement, bool filtered = false) {
if (filtered && filteredCount) {
++(*filteredCount);
} else if (bands.size() > 0) {
auto itr = bands.upper_bound(measurement);
ASSERT(itr != bands.end());
++(*itr->second);
}
}
void clearBands() {
logger = Void();
bands.clear();
filteredCount.reset();
cc.reset();
}
~LatencyBands() { clearBands(); }
private:
std::map<double, std::unique_ptr<Counter>> bands;
std::unique_ptr<Counter> filteredCount;
std::string name;
UID id;
double loggingInterval;
std::unique_ptr<CounterCollection> cc;
Future<Void> logger;
void insertBand(double value) {
bands.emplace(std::make_pair(value, std::make_unique<Counter>(format("Band%f", value), *cc)));
}
};
class LatencySample {
public:
LatencySample(std::string name, UID id, double loggingInterval, int sampleSize)
: name(name), id(id), sample(sampleSize), sampleStart(now()) {
logger = recurring([this]() { logSample(); }, loggingInterval);
}
void addMeasurement(double measurement) { sample.addSample(measurement); }
private:
std::string name;
UID id;
double sampleStart;
ContinuousSample<double> sample;
Future<Void> logger;
void logSample() {
TraceEvent(name.c_str(), id)
.detail("Count", sample.getPopulationSize())
.detail("Elapsed", now() - sampleStart)
.detail("Min", sample.min())
.detail("Max", sample.max())
.detail("Mean", sample.mean())
.detail("Median", sample.median())
.detail("P25", sample.percentile(0.25))
.detail("P90", sample.percentile(0.9))
.detail("P95", sample.percentile(0.95))
.detail("P99", sample.percentile(0.99))
.detail("P99.9", sample.percentile(0.999))
.trackLatest(id.toString() + "/" + name);
sample.clear();
sampleStart = now();
}
};
#endif