2017-09-05 14:15:56 -06:00
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<!--{
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"Title": "Diagnostics",
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"Template": true
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}-->
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<h2 id="introduction">Introduction</h2>
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<p>
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The Go ecosystem provides a large suite of APIs and tools to
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diagnose logic and performance problems in Go programs. This page
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summarizes the available tools and helps Go users pick the right one
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for their specific problem.
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</p>
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<p>
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Diagnostics solutions can be categorized into the following groups:
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</p>
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<ul>
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<li><strong>Profiling</strong>: Profiling tools analyze the complexity and costs of a
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Go program such as its memory usage and frequently called
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functions to identify the expensive sections of a Go program.</li>
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<li><strong>Tracing</strong>: Tracing is a way to instrument code to analyze latency
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throughout the lifecycle of a call or user request. Traces provide an
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overview of how much latency each component contributes to the overall
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latency in a system. Traces can span multiple Go processes.</li>
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<li><strong>Debugging</strong>: Debugging allows us to pause a Go program and examine
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its execution. Program state and flow can be verified with debugging.</li>
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<li><strong>Runtime statistics and events</strong>: Collection and analysis of runtime stats and events
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provides a high-level overview of the health of Go programs. Spikes/dips of metrics
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helps us to identify changes in throughput, utilization, and performance.</li>
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</ul>
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<p>
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Note: Some diagnostics tools may interfere with each other. For example, precise
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memory profiling skews CPU profiles and goroutine blocking profiling affects scheduler
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trace. Use tools in isolation to get more precise info.
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</p>
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<h2 id="profiling">Profiling</h2>
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<p>
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Profiling is useful for identifying expensive or frequently called sections
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of code. The Go runtime provides <a href="https://golang.org/pkg/runtime/pprof/">
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profiling data</a> in the format expected by the
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<a href="https://github.com/google/pprof/blob/master/doc/pprof.md">pprof visualization tool</a>.
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The profiling data can be collected during testing
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via <code>go test</code> or endpoints made available from the <a href="/pkg/net/http/pprof/">
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net/http/pprof</a> package. Users need to collect the profiling data and use pprof tools to filter
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and visualize the top code paths.
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</p>
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<p>Predefined profiles provided by the <a href="/pkg/runtime/pprof">runtime/pprof</a> package:</p>
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<ul>
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<li>
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<strong>cpu</strong>: CPU profile determines where a program spends
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its time while actively consuming CPU cycles (as opposed to while sleeping or waiting for I/O).
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</li>
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<li>
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<strong>heap</strong>: Heap profile reports memory allocation samples;
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used to monitor current and historical memory usage, and to check for memory leaks.
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</li>
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<li>
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<strong>threadcreate</strong>: Thread creation profile reports the sections
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of the program that lead the creation of new OS threads.
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</li>
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<li>
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<strong>goroutine</strong>: Goroutine profile reports the stack traces of all current goroutines.
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</li>
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<li>
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<strong>block</strong>: Block profile shows where goroutines block waiting on synchronization
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primitives (including timer channels). Block profile is not enabled by default;
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use <code>runtime.SetBlockProfileRate</code> to enable it.
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</li>
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<li>
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<strong>mutex</strong>: Mutex profile reports the lock contentions. When you think your
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CPU is not fully utilized due to a mutex contention, use this profile. Mutex profile
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is not enabled by default, see <code>runtime.SetMutexProfileFraction</code> to enable it.
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</li>
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</ul>
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<p><strong>What other profilers can I use to profile Go programs?</strong></p>
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<p>
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On Linux, <a href="https://perf.wiki.kernel.org/index.php/Tutorial">perf tools</a>
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can be used for profiling Go programs. Perf can profile
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and unwind cgo/SWIG code and kernel, so it can be useful to get insights into
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native/kernel performance bottlenecks. On macOS,
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<a href="https://developer.apple.com/library/content/documentation/DeveloperTools/Conceptual/InstrumentsUserGuide/">Instruments</a>
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suite can be used profile Go programs.
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</p>
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<p><strong>Can I profile my production services?</strong></p>
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<p>Yes. It is safe to profile programs in production, but enabling
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some profiles (e.g. the CPU profile) adds cost. You should expect to
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see performance downgrade. The performance penalty can be estimated
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by measuring the overhead of the profiler before turning it on in
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production.
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</p>
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<p>
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You may want to periodically profile your production services.
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Especially in a system with many replicas of a single process, selecting
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a random replica periodically is a safe option.
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Select a production process, profile it for
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X seconds for every Y seconds and save the results for visualization and
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analysis; then repeat periodically. Results may be manually and/or automatically
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reviewed to find problems.
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Collection of profiles can interfere with each other,
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so it is recommended to collect only a single profile at a time.
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</p>
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<p>
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<strong>What are the best ways to visualize the profiling data?</strong>
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</p>
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<p>
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The Go tools provide text, graph, and <a href="http://valgrind.org/docs/manual/cl-manual.html">callgrind</a>
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visualization of the profile data using
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<code><a href="https://github.com/google/pprof/blob/master/doc/pprof.md">go tool pprof</a></code>.
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Read <a href="https://blog.golang.org/profiling-go-programs">Profiling Go programs</a>
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to see them in action.
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</p>
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<p>
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<img width="800" src="https://storage.googleapis.com/golangorg-assets/pprof-text.png">
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<br>
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<small>Listing of the most expensive calls as text.</small>
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</p>
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<p>
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<img width="800" src="https://storage.googleapis.com/golangorg-assets/pprof-dot.png">
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<br>
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<small>Visualization of the most expensive calls as a graph.</small>
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</p>
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<p>Weblist view displays the expensive parts of the source line by line in
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an HTML page. In the following example, 530ms is spent in the
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<code>runtime.concatstrings</code> and cost of each line is presented
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in the listing.</p>
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<p>
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<img width="800" src="https://storage.googleapis.com/golangorg-assets/pprof-weblist.png">
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<br>
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<small>Visualization of the most expensive calls as weblist.</small>
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</p>
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<p>
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Another way to visualize profile data is a <a href="http://www.brendangregg.com/flamegraphs.html">flame graph</a>.
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Flame graphs allow you to move in a specific ancestry path, so you can zoom
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in/out of specific sections of code.
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The <a href="https://github.com/google/pprof">upstream pprof</a>
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has support for flame graphs.
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</p>
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<p>
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<img width="800" src="https://storage.googleapis.com/golangorg-assets/flame.png">
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<br>
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<small>Flame graphs offers visualization to spot the most expensive code-paths.</small>
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</p>
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<p><strong>Am I restricted to the built-in profiles?</strong></p>
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<p>
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Additionally to what is provided by the runtime, Go users can create
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their custom profiles via <a href="/pkg/runtime/pprof/#Profile">pprof.Profile</a>
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and use the existing tools to examine them.
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</p>
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<p><strong>Can I serve the profiler handlers (/debug/pprof/...) on a different path and port?</strong></p>
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<p>
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Yes. The <code>net/http/pprof</code> package registers its handlers to the default
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mux by default, but you can also register them yourself by using the handlers
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exported from the package.
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</p>
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<p>
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For example, the following example will serve the pprof.Profile
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handler on :7777 at /custom_debug_path/profile:
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</p>
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<p>
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<pre>
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package main
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import (
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"log"
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"net/http"
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"net/http/pprof"
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)
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func main() {
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mux := http.NewServeMux()
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mux.HandleFunc("/custom_debug_path/profile", pprof.Profile)
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log.Fatal(http.ListenAndServe(":7777", mux))
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}
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</pre>
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</p>
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<h2 id="tracing">Tracing</h2>
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<p>
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Tracing is a way to instrument code to analyze latency throughout the
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lifecycle of a chain of calls. Go provides
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<a href="https://godoc.org/golang.org/x/net/trace">golang.org/x/net/trace</a>
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package as a minimal tracing backend per Go node and provides a minimal
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instrumentation library with a simple dashboard. Go also provides
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an execution tracer to trace the runtime events within an interval.
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</p>
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<p>Tracing enables us to:</p>
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<ul>
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<li>Instrument and profile application latency in a Go process.</li>
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<li>Measure the cost of specific calls in a long chain of calls.</li>
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<li>Figure out the utilization and performance improvements.
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Bottlenecks are not always obvious without tracing data.</li>
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</ul>
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<p>
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In monolithic systems, it's relatively easy to collect diagnostic data
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from the building blocks of a program. All modules live within one
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process and share common resources to report logs, errors, and other
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diagnostic information. Once your system grows beyond a single process and
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starts to become distributed, it becomes harder to follow a call starting
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from the front-end web server to all of its back-ends until a response is
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returned back to the user. This is where distributed tracing plays a big
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role to instrument and analyze your production systems.
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</p>
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<p>
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Distributed tracing is a way to instrument code to analyze latency throughout
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the lifecycle of a user request. When a system is distributed and when
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conventional profiling and debugging tools don’t scale, you might want
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to use distributed tracing tools to analyze the performance of your user
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requests and RPCs.
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</p>
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<p>Distributed tracing enables us to:</p>
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<ul>
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<li>Instrument and profile application latency in a large system.</li>
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<li>Track all RPCs within the lifecycle of a user request and see integration issues
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that are only visible in production.</li>
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<li>Figure out performance improvements that can be applied to our systems.
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Many bottlenecks are not obvious before the collection of tracing data.</li>
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</ul>
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<p>The Go ecosystem provides various distributed tracing libraries per tracing system
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and backend-agnostic ones.</p>
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<p><strong>Is there a way to automatically intercept each function call and create traces?</strong></p>
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<p>
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Go doesn’t provide a way to automatically intercept every function call and create
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trace spans. You need to manually instrument your code to create, end, and annotate spans.
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</p>
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<p><strong>How should I propagate trace headers in Go libraries?</strong></p>
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<p>
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You can propagate trace identifiers and tags in the
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<a href="/pkg/context#Context"><code>context.Context</code></a>.
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There is no canonical trace key or common representation of trace headers
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in the industry yet. Each tracing provider is responsible for providing propagation
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utilities in their Go libraries.
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</p>
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<p>
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<strong>What other low-level events from the standard library or
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runtime can be included in a trace?</strong>
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</p>
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<p>
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The standard library and runtime are trying to expose several additional APIs
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to notify on low level internal events. For example,
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<a href="/pkg/net/http/httptrace#ClientTrace"><code>httptrace.ClientTrace</code></a>
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provides APIs to follow low-level events in the life cycle of an outgoing request.
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There is an ongoing effort to retrieve low-level runtime events from
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the runtime execution tracer and allow users to define and record their user events.
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</p>
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<h2 id="debugging">Debugging</h2>
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<p>
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Debugging is the process of identifying why a program misbehaves.
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Debuggers allow us to understand a program’s execution flow and current state.
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There are several styles of debugging; this section will only focus on attaching
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a debugger to a program and core dump debugging.
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</p>
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<p>Go users mostly use the following debuggers:</p>
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<ul>
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<li>
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<a href="https://github.com/derekparker/delve">Delve</a>:
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Delve is a debugger for the Go programming language. It has
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support for Go’s runtime concepts and built-in types. Delve is
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trying to be a fully featured reliable debugger for Go programs.
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</li>
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<li>
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<a href="https://golang.org/doc/gdb">GDB</a>:
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Go provides GDB support via the standard Go compiler and Gccgo.
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The stack management, threading, and runtime contain aspects that differ
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enough from the execution model GDB expects that they can confuse the
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debugger, even when the program is compiled with gccgo. Even though
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GDB can be used to debug Go programs, it is not ideal and may
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create confusion.
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</li>
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</ul>
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<p><strong>How well do debuggers work with Go programs?</strong></p>
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<p>
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2017-12-19 13:06:57 -07:00
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The <code>gc</code> compiler performs optimizations such as
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function inlining and variable registerization. These optimizations
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sometimes make debugging with debuggers harder. There is an ongoing
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effort to improve the quality of the DWARF information generated for
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optimized binaries. Until those improvements are available, we recommend
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disabling optimizations when building the code being debugged. The following
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command builds a package with no compiler optimizations:
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<p>
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<pre>
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2017-12-19 13:06:57 -07:00
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$ go build -gcflags=all="-N -l"
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</pre>
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</p>
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2017-12-19 13:06:57 -07:00
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As part of the improvement effort, Go 1.10 introduced a new compiler
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flag <code>-dwarflocationlists</code>. The flag causes the compiler to
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add location lists that helps debuggers work with optimized binaries.
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The following command builds a package with optimizations but with
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the DWARF location lists:
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2017-09-05 14:15:56 -06:00
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<p>
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<pre>
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$ go build -gcflags="-dwarflocationlists=true"
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</pre>
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</p>
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<p><strong>What’s the recommended debugger user interface?</strong></p>
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<p>
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Even though both delve and gdb provides CLIs, most editor integrations
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and IDEs provides debugging-specific user interfaces. Please refer to
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the <a href="/doc/editors.html">editors guide</a> to see the options
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with debugger UI support.
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</p>
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<p><strong>Is it possible to do postmortem debugging with Go programs?</strong></p>
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<p>
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A core dump file is a file that contains the memory dump of a running
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process and its process status. It is primarily used for post-mortem
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debugging of a program and to understand its state
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while it is still running. These two cases make debugging of core
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dumps a good diagnostic aid to postmortem and analyze production
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services. It is possible to obtain core files from Go programs and
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use delve or gdb to debug, see the
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<a href="https://golang.org/wiki/CoreDumpDebugging">core dump debugging</a>
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page for a step-by-step guide.
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</p>
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<h2 id="runtime">Runtime statistics and events</h2>
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<p>
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The runtime provides stats and reporting of internal events for
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users to diagnose performance and utilization problems at the
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runtime level.
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</p>
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<p>
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Users can monitor these stats to better understand the overall
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health and performance of Go programs.
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Some frequently monitored stats and states:
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</p>
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<ul>
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<li><code><a href="/pkg/runtime/#ReadMemStats">runtime.ReadMemStats</a></code>
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reports the metrics related to heap
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allocation and garbage collection. Memory stats are useful for
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monitoring how much memory resources a process is consuming,
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whether the process can utilize memory well, and to catch
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memory leaks.</li>
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<li><code><a href="/pkg/runtime/debug/#ReadGCStats">debug.ReadGCStats</a></code>
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reads statistics about garbage collection.
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It is useful to see how much of the resources are spent on GC pauses.
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It also reports a timeline of garbage collector pauses and pause time percentiles.</li>
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<li><code><a href="/pkg/runtime/debug/#Stack">debug.Stack</a></code>
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returns the current stack trace. Stack trace
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is useful to see how many goroutines are currently running,
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what they are doing, and whether they are blocked or not.</li>
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<li><code><a href="/pkg/runtime/debug/#WriteHeapDump">debug.WriteHeapDump</a></code>
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suspends the execution of all goroutines
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and allows you to dump the heap to a file. A heap dump is a
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snapshot of a Go process' memory at a given time. It contains all
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allocated objects as well as goroutines, finalizers, and more.</li>
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<li><code><a href="/pkg/runtime#NumGoroutine">runtime.NumGoroutine</a></code>
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returns the number of current goroutines.
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The value can be monitored to see whether enough goroutines are
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2017-11-21 09:00:58 -07:00
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utilized, or to detect goroutine leaks.</li>
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2017-09-05 14:15:56 -06:00
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</ul>
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<h3 id="execution-tracer">Execution tracer</h3>
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<p>Go comes with a runtime execution tracer to capture a wide range
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of runtime events. Scheduling, syscall, garbage collections,
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heap size, and other events are collected by runtime and available
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for visualization by the go tool trace. Execution tracer is a tool
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to detect latency and utilization problems. You can examine how well
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the CPU is utilized, and when networking or syscalls are a cause of
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preemption for the goroutines.</p>
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<p>Tracer is useful to:</p>
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<ul>
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<li>Understand how your goroutines execute.</li>
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<li>Understand some of the core runtime events such as GC runs.</li>
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<li>Identify poorly parallelized execution.</li>
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</ul>
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<p>However, it is not great for identifying hot spots such as
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analyzing the cause of excessive memory or CPU usage.
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Use profiling tools instead first to address them.</p>
|
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<p>
|
|
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|
|
<img width="800" src="https://storage.googleapis.com/golangorg-assets/tracer-lock.png">
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</p>
|
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<p>Above, the go tool trace visualization shows the execution started
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fine, and then it became serialized. It suggests that there might
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be lock contention for a shared resource that creates a bottleneck.</p>
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<p>See <a href="https://golang.org/cmd/trace/"><code>go tool trace</code></a>
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to collect and analyze runtime traces.
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|
</p>
|
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|
|
<h3 id="godebug">GODEBUG</h3>
|
|
|
|
|
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<p>Runtime also emits events and information if
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|
<a href="https://golang.org/pkg/runtime/#hdr-Environment_Variables">GODEBUG</a>
|
|
|
|
|
environmental variable is set accordingly.</p>
|
|
|
|
|
|
|
|
|
|
<ul>
|
|
|
|
|
<li>GODEBUG=gctrace=1 prints garbage collector events at
|
2017-11-21 09:00:58 -07:00
|
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|
|
each collection, summarizing the amount of memory collected
|
2017-09-05 14:15:56 -06:00
|
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|
|
and the length of the pause.</li>
|
2017-11-21 09:00:58 -07:00
|
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<li>GODEBUG=schedtrace=X prints scheduling events every X milliseconds.</li>
|
2017-09-05 14:15:56 -06:00
|
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|
|
</ul>
|