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Published: Apr 8, 2018 License: Apache-2.0

README

Profiling Code

We can use the go tooling to inspect and profile our programs. Profiling is more of a journey and detective work. It requires some understanding about the application and expectations. The profiling data in and of itself is just raw numbers. We have to give it meaning and understanding.

The Basics of Profiling

"Those who can make you believe absurdities can make you commit atrocities" - Voltaire

How does a profiler work?

A profiler runs your program and configures the operating system to interrupt it at regular intervals. This is done by sending SIGPROF to the program being profiled, which suspends and transfers execution to the profiler. The profiler then grabs the program counter for each executing thread and restarts the program.

Profiling do's and don't's

Before you profile, you must have a stable environment to get repeatable results.

  • The machine must be idle—don't profile on shared hardware, don't browse the web while waiting for a long benchmark to run.
  • Watch out for power saving and thermal scaling.
  • Avoid virtual machines and shared cloud hosting; they are too noisy for consistent measurements.

If you can afford it, buy dedicated performance test hardware. Rack them, disable all the power management and thermal scaling and never update the software on those machines.

For everyone else, have a before and after sample and run them multiple times to get consistent results.

Types of Profiling

CPU profiling
CPU profiling is the most common type of profile. When CPU profiling is enabled, the runtime will interrupt itself every 10ms and record the stack trace of the currently running goroutines. Once the profile is saved to disk, we can analyse it to determine the hottest code paths. The more times a function appears in the profile, the more time that code path is taking as a percentage of the total runtime.

Memory profiling
Memory profiling records the stack trace when a heap allocation is made. Memory profiling, like CPU profiling is sample based. By default memory profiling samples 1 in every 1000 allocations. This rate can be changed. Stack allocations are assumed to be free and are not tracked in the memory profile. Because of memory profiling is sample based and because it tracks allocations not use, using memory profiling to determine your application's overall memory usage is difficult.

Block profiling
Block profiling is quite unique. A block profile is similar to a CPU profile, but it records the amount of time a goroutine spent waiting for a shared resource. This can be useful for determining concurrency bottlenecks in your application. Block profiling can show you when a large number of goroutines could make progress, but were blocked.

Blocking includes:

  • Sending or receiving on a unbuffered channel.
  • Sending to a full channel, receiving from an empty one.
  • Trying to Lock a sync.Mutex that is locked by another goroutine.
  • Block profiling is a very specialised tool, it should not be used until you believe you have eliminated all your CPU and memory usage bottlenecks.

One profile at at time
Profiling is not free. Profiling has a moderate, but measurable impact on program performance—especially if you increase the memory profile sample rate. Most tools will not stop you from enabling multiple profiles at once. If you enable multiple profiles at the same time, they will observe their own interactions and skew your results.

Do not enable more than one kind of profile at a time.

Hints to interpret what you see in the profile

If you see lots of time spent in runtime.mallocgc function, the program potentially makes excessive amount of small memory allocations. The profile will tell you where the allocations are coming from. See the memory profiler section for suggestions on how to optimize this case.

If lots of time is spent in channel operations, sync.Mutex code and other synchronization primitives or System component, the program probably suffers from contention. Consider to restructure program to eliminate frequently accessed shared resources. Common techniques for this include sharding/partitioning, local buffering/batching and copy-on-write technique.

If lots of time is spent in syscall.Read/Write, the program potentially makes excessive amount of small reads and writes. Bufio wrappers around os.File or net.Conn can help in this case.

If lots of time is spent in GC component, the program either allocates too many transient objects or heap size is very small so garbage collections happen too frequently.

  • Large objects affect memory consumption and GC time, while large number of tiny allocations affects execution speed.

  • Combine values into larger values. This will reduce number of memory allocations (faster) and also reduce pressure on garbage collector (faster garbage collections).

  • Values that do not contain any pointers are not scanned by garbage collector. Removing pointers from actively used value can positively impact garbage collection time.

Rules of Performance

  1. Never guess about performance.
  2. Measurements must be relevant.
  3. Profile before you decide something is performance critical.
  4. Test to know you are correct.

Installing Tools

hey
hey is a modern HTTP benchmarking tool capable of generating the load you need to run tests. It's built using the Go language and leverages goroutines for behind the scenes async IO and concurrency.

go get -u github.com/rakyll/hey

Dave Cheney's Profiling Presentation:

Much of what I have learned comes from Dave and working on solving problems. This slide deck is a great place to start. Much of this material can be found in the material below.

http://go-talks.appspot.com/github.com/davecheney/presentations/seven.slide#1

Profiling, Debugging and Optimization Reading

Here is more reading and videos to also help get you started.

Profiling Go Programs - Go Team
Profiling & Optimizing in Go - Brad Fitzpatrick
Go Dynamic Tools - Dmitry Vyukov
How NOT to Measure Latency - Gil Tene
Go Performance Tales - Jason Moiron
Debugging performance issues in Go programs - Dmitry Vyukov
Reduce allocation in Go code - Python Bytes
Write High Performance Go - Dave Cheney
Static analysis features of godoc - Go Team
Seven ways to profile a Go program - Dave Cheney
runtime: goroutine execution stalled during GC - Caleb Spare
Go's execution tracer - Rhys Hiltner
Using Instruments to profile Go programs - rakyll
Fighting latency: the CPU profiler is not your ally - Filippo Valsorda
go tool trace - Will Sewell

Go and OS Tooling

time

The time command provide information that can help you get a sense how your program is performing.

Use the time command to see data about building the program. $ cd $GOPATH/src/github.com/ardanlabs/gotraining/topics/go/profiling/project $ /usr/bin/time -lp go build -- Mac OS X $ /usr/bin/time -v go build -- Linux

perf

If you're a linux user, then perf(1) is a great tool for profiling applications. Now we have frame pointers, perf can profile Go applications.

$ go build -toolexec="perf stat" cmd/compile/internal/gc
# cmd/compile/internal/gc

Performance counter stats for '/home/dfc/go/pkg/tool/linux_amd64/compile -o $WORK/cmd/compile/internal/gc.a -trimpath $WORK -p cmd/compile/internal/gc -complete -buildid 87cd803267511b4d9e753d68b5b66a70e2f878c4 -D _/home/dfc/go/src/cmd/compile/internal/gc -I $WORK -pack ./alg.go ./align.go ./bexport.go ./bimport.go ./builtin.go ./bv.go ./cgen.go ./closure.go ./const.go ./cplx.go ./dcl.go ./esc.go ./export.go ./fmt.go ./gen.go ./go.go ./gsubr.go ./init.go ./inl.go ./lex.go ./magic.go ./main.go ./mpfloat.go ./mpint.go ./obj.go ./opnames.go ./order.go ./parser.go ./pgen.go ./plive.go ./popt.go ./racewalk.go ./range.go ./reflect.go ./reg.go ./select.go ./sinit.go ./sparselocatephifunctions.go ./ssa.go ./subr.go ./swt.go ./syntax.go ./type.go ./typecheck.go ./universe.go ./unsafe.go ./util.go ./walk.go':

   7026.140760 task-clock (msec)         #    1.283 CPUs utilized          
         1,665 context-switches          #    0.237 K/sec                  
            39 cpu-migrations            #    0.006 K/sec                  
        77,362 page-faults               #    0.011 M/sec                  
21,769,537,949 cycles                    #    3.098 GHz                     [83.41%]
11,671,235,864 stalled-cycles-frontend   #   53.61% frontend cycles idle    [83.31%]
 6,839,727,058 stalled-cycles-backend    #   31.42% backend  cycles idle    [66.65%]
27,157,950,447 instructions              #    1.25  insns per cycle        
                                         #    0.43  stalled cycles per insn [83.25%]
 5,351,057,260 branches                  #  761.593 M/sec                   [83.49%]
   118,150,150 branch-misses             #    2.21% of all branches         [83.15%]

   5.476816754 seconds time elapsed

Basic Go Profiling

Learn the basics of reading Stack Traces.
Stack Traces and Core Dumps

Learn the basics of using GODEBUG.
GODEBUG

Learn the basics of using memory and cpu profiling.
Memory and CPU Profiling

Learn the basics of using http/pprof.
pprof Profiling

Learn the basics of blocking profiling.
Blocking Profiling

Learn the basics of mutex profiling.
Mutex Profiling

Learn the basics of tracing.
Tracing

Learn the basics of profiling and tracing a larger application.
Real World Example

Godoc Analysis

The godoc tool can help you perform static analysis on your code.

// Perform a pointer analysis and then run the godoc website.
$ godoc -analysis pointer -http=:8080

Static analysis features of godoc - Go Team

HTTP Tracing

HTTP tracing facilitate the gathering of fine-grained information throughout the lifecycle of an HTTP client request.

HTTP Tracing Package


All material is licensed under the Apache License Version 2.0, January 2004.

Directories

Path Synopsis
Sample program that implements a simple web service that will allow us to explore how to use the GODEBUG variable.
Sample program that implements a simple web service that will allow us to explore how to use the GODEBUG variable.
http_trace
example1
Sample program to show how the httptrace package provides a number of hooks to gather information during an HTTP round trip about a variety of events.
Sample program to show how the httptrace package provides a number of hooks to gather information during an HTTP round trip about a variety of events.
example2
Sample program to show how to use the http trace with a unique Client and Transport.
Sample program to show how to use the http trace with a unique Client and Transport.
Sample program that takes a stream of bytes and looks for the bytes “elvis” and when they are found, replace them with “Elvis”.
Sample program that takes a stream of bytes and looks for the bytes “elvis” and when they are found, replace them with “Elvis”.
Sample program that implements a simple web service that will allow us to explore how to use the http/pprof tooling.
Sample program that implements a simple web service that will allow us to explore how to use the http/pprof tooling.
This program provides a sample web service that uses concurrency and channels to perform a coordinated set of asynchronous searches.
This program provides a sample web service that uses concurrency and channels to perform a coordinated set of asynchronous searches.
search
Package search manages the searching of results against different news feeds.
Package search manages the searching of results against different news feeds.
service
Package service maintains the logic for the web service.
Package service maintains the logic for the web service.
stack_trace
example1
Sample program to show how to read a stack trace.
Sample program to show how to read a stack trace.
example2
Sample program to show how to read a stack trace when it packs values.
Sample program to show how to read a stack trace when it packs values.
example3
Sample program that implements a simple web service that will allow us to explore how to look at core dumps.
Sample program that implements a simple web service that will allow us to explore how to look at core dumps.
Sample program that performs a series of I/O related tasks to better understand tracing in Go.
Sample program that performs a series of I/O related tasks to better understand tracing in Go.

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