foundationdb/flow/Histogram.cpp

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/*
* Histogram.cpp
*
* 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.
*/
#include <flow/Histogram.h>
#include <flow/flow.h>
#include <flow/UnitTest.h>
// TODO: remove dependency on fdbrpc.
// we need to be able to check if we're in simulation so that the histograms are properly
// scoped to the right "machine".
// either we pull g_simulator into flow, or flow (and the I/O path) will be unable to log performance
// metrics.
#include <fdbrpc/simulator.h>
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#include <limits>
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// pull in some global pointers too: These types are implemented in fdbrpc/sim2.actor.cpp, which is not available here.
// Yuck. If you're not using the simulator, these will remain null, and all should be well.
// TODO: create a execution context abstraction that allows independent flow instances within a process.
// The simulator would be the main user of it, and histogram would be the only other user (for now).
ISimulator* g_pSimulator = nullptr;
thread_local ISimulator::ProcessInfo* ISimulator::currentProcess = nullptr;
// Fallback registry when we're not in simulation -- if we had execution contexts we wouldn't need to check if
// we have a simulated contex here; we'd just use the current context regardless.
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static HistogramRegistry* globalHistograms = nullptr;
#pragma region HistogramRegistry
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HistogramRegistry& GetHistogramRegistry() {
ISimulator::ProcessInfo* info = g_network && g_network->isSimulated() ? g_simulator.getCurrentProcess() : nullptr;
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if (info) {
// in simulator; scope histograms to simulated process
return info->histograms;
}
// avoid link order issues where the registry hasn't been initialized, but we're
// instantiating a histogram
if (globalHistograms == nullptr) {
// Note: This will show up as a leak on shutdown, but we're OK with that.
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globalHistograms = new HistogramRegistry();
}
return *globalHistograms;
}
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void HistogramRegistry::registerHistogram(Histogram* h) {
if (histograms.find(h->name()) != histograms.end()) {
TraceEvent(SevError, "HistogramDoubleRegistered").detail("group", h->group).detail("op", h->op);
ASSERT(false);
}
histograms.insert(std::pair<std::string, Histogram*>(h->name(), h));
}
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void HistogramRegistry::unregisterHistogram(Histogram* h) {
std::string name = h->name();
if (histograms.find(name) == histograms.end()) {
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TraceEvent(SevError, "HistogramNotRegistered").detail("group", h->group).detail("op", h->op);
}
int count = histograms.erase(name);
ASSERT(count == 1);
}
Histogram* HistogramRegistry::lookupHistogram(std::string const& name) {
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auto h = histograms.find(name);
if (h == histograms.end()) {
return nullptr;
}
return h->second;
}
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void HistogramRegistry::logReport(double elapsed) {
for (auto& i : histograms) {
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// Reset all buckets in writeToLog function
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i.second->writeToLog(elapsed);
}
}
void HistogramRegistry::clear() {
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for (auto& i : histograms) {
i.second->clear();
}
}
#pragma endregion // HistogramRegistry
#pragma region Histogram
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const char* const Histogram::UnitToStringMapper[] = { "microseconds", "bytes", "bytes_per_second",
"percentage", "count", "none" };
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void Histogram::writeToLog(double elapsed) {
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bool active = false;
for (uint32_t i = 0; i < 32; i++) {
if (buckets[i]) {
active = true;
break;
}
}
if (!active) {
return;
}
TraceEvent e(SevInfo, "Histogram");
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e.detail("Group", group).detail("Op", op).detail("Unit", UnitToStringMapper[(size_t)unit]);
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if (elapsed > 0)
e.detail("Elapsed", elapsed);
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int totalCount = 0;
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for (uint32_t i = 0; i < 32; i++) {
uint64_t value = uint64_t(1) << (i + 1);
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if (buckets[i]) {
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totalCount += buckets[i];
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switch (unit) {
case Unit::microseconds:
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e.detail(format("LessThan%u.%03u", int(value / 1000), int(value % 1000)), buckets[i]);
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break;
case Unit::bytes:
case Unit::bytes_per_second:
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e.detail(format("LessThan%" PRIu64, value), buckets[i]);
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break;
case Unit::percentageLinear:
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e.detail(format("LessThan%f", (i + 1) * 0.04), buckets[i]);
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break;
case Unit::countLinear:
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value = uint64_t((i + 1) * ((upperBound - lowerBound) / 31.0));
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e.detail(format("LessThan%" PRIu64, value), buckets[i]);
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break;
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case Unit::MAXHISTOGRAMUNIT:
e.detail(format("Default%u", i), buckets[i]);
break;
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default:
ASSERT(false);
}
}
}
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e.detail("TotalCount", totalCount);
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clear();
}
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std::string Histogram::drawHistogram() {
std::stringstream result;
const char* verticalLine = "\0";
const char* origin = "\0";
const char* emptyCell = "------\0";
const char* halfCell = "---▄▄▄\0";
const char* fullCell = "---███\0";
const char* xFull = "---▀▀▀\0";
const char* xEmpty = "------\0";
const char* lineEnd = "--- \0";
const unsigned int width = std::strlen(emptyCell);
int max_lines = 23;
uint32_t total = 0;
double maxPct = 0;
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for (int i = 0; i < 32; i++) {
total += buckets[i];
}
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for (int i = 0; i < 32; i++) {
maxPct = std::max(maxPct, (100.0 * buckets[i]) / total);
}
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double intervalSize = (maxPct < (max_lines - 3)) ? 1 : maxPct / (max_lines - 3);
unsigned int lines = (maxPct < (max_lines - 3)) ? (unsigned int)maxPct : (max_lines - 3);
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result << "Total Inputs: " << total << std::fixed << "\n";
result << "Percent"
<< "\n";
for (int l = 0; l < lines; l++) {
double currHeight = (lines - l) * intervalSize;
double halfFullHeight = currHeight - intervalSize / 4;
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result << std::setw(6) << std::setprecision(2) << currHeight << " " << verticalLine;
for (int i = 0; i < 32; i++) {
double pct = (100.0 * buckets[i]) / total;
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if (pct > currHeight)
result << fullCell;
else if (pct > halfFullHeight)
result << halfCell;
else
result << emptyCell;
}
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result << lineEnd << "\n";
}
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result << " 0.00 " << origin;
for (int i = 0; i < 32; i++) {
double pct = (100.0 * buckets[i]) / total;
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if (pct > intervalSize / 4)
result << xFull;
else
result << xEmpty;
}
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result << lineEnd << "\n";
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result << std::string(9, ' ');
for (int i = 0; i < 32; i++) {
result << std::left << std::setw(width) << " B" + std::to_string(i);
}
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result << "\n";
return result.str();
}
#pragma endregion // Histogram
TEST_CASE("/flow/histogram/smoke_test") {
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{
Reference<Histogram> h =
Histogram::getHistogram(LiteralStringRef("smoke_test"), LiteralStringRef("counts"), Histogram::Unit::bytes);
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h->sample(0);
ASSERT(h->buckets[0] == 1);
h->sample(1);
ASSERT(h->buckets[0] == 2);
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h->sample(2);
ASSERT(h->buckets[1] == 1);
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GetHistogramRegistry().logReport();
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ASSERT(h->buckets[0] == 0);
h->sample(0);
ASSERT(h->buckets[0] == 1);
h = Histogram::getHistogram(
LiteralStringRef("smoke_test"), LiteralStringRef("counts2"), Histogram::Unit::bytes);
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// confirm that old h was deallocated.
h = Histogram::getHistogram(LiteralStringRef("smoke_test"), LiteralStringRef("counts"), Histogram::Unit::bytes);
ASSERT(h->buckets[0] == 0);
h = Histogram::getHistogram(
LiteralStringRef("smoke_test"), LiteralStringRef("times"), Histogram::Unit::microseconds);
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h->sampleSeconds(0.000000);
h->sampleSeconds(0.0000019);
ASSERT(h->buckets[0] == 2);
h->sampleSeconds(0.0000021);
ASSERT(h->buckets[1] == 1);
h->sampleSeconds(0.000015);
ASSERT(h->buckets[3] == 1);
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h->sampleSeconds(4400.0);
ASSERT(h->buckets[31] == 1);
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GetHistogramRegistry().logReport();
}
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// h has been deallocated. Does this crash?
GetHistogramRegistry().logReport();
return Void();
}