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Updates #38485. Change-Id: I46f515973c0a31d7c3e0e05ce006121c60c4041e Reviewed-on: https://go-review.googlesource.com/c/go/+/268497 Trust: Cherry Zhang <cherryyz@google.com> Reviewed-by: Dmitri Shuralyov <dmitshur@golang.org> Reviewed-by: Ian Lance Taylor <iant@golang.org>
441 lines
10 KiB
HTML
441 lines
10 KiB
HTML
<!--{
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"Title": "Data Race Detector",
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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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Data races are among the most common and hardest to debug types of bugs in concurrent systems.
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A data race occurs when two goroutines access the same variable concurrently and at least one of the accesses is a write.
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See the <a href="/ref/mem/">The Go Memory Model</a> for details.
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</p>
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<p>
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Here is an example of a data race that can lead to crashes and memory corruption:
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</p>
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<pre>
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func main() {
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c := make(chan bool)
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m := make(map[string]string)
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go func() {
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m["1"] = "a" // First conflicting access.
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c <- true
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}()
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m["2"] = "b" // Second conflicting access.
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<-c
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for k, v := range m {
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fmt.Println(k, v)
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}
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}
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</pre>
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<h2 id="Usage">Usage</h2>
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<p>
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To help diagnose such bugs, Go includes a built-in data race detector.
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To use it, add the <code>-race</code> flag to the go command:
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</p>
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<pre>
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$ go test -race mypkg // to test the package
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$ go run -race mysrc.go // to run the source file
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$ go build -race mycmd // to build the command
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$ go install -race mypkg // to install the package
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</pre>
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<h2 id="Report_Format">Report Format</h2>
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<p>
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When the race detector finds a data race in the program, it prints a report.
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The report contains stack traces for conflicting accesses, as well as stacks where the involved goroutines were created.
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Here is an example:
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</p>
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<pre>
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WARNING: DATA RACE
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Read by goroutine 185:
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net.(*pollServer).AddFD()
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src/net/fd_unix.go:89 +0x398
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net.(*pollServer).WaitWrite()
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src/net/fd_unix.go:247 +0x45
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net.(*netFD).Write()
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src/net/fd_unix.go:540 +0x4d4
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net.(*conn).Write()
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src/net/net.go:129 +0x101
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net.func·060()
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src/net/timeout_test.go:603 +0xaf
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Previous write by goroutine 184:
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net.setWriteDeadline()
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src/net/sockopt_posix.go:135 +0xdf
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net.setDeadline()
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src/net/sockopt_posix.go:144 +0x9c
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net.(*conn).SetDeadline()
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src/net/net.go:161 +0xe3
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net.func·061()
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src/net/timeout_test.go:616 +0x3ed
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Goroutine 185 (running) created at:
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net.func·061()
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src/net/timeout_test.go:609 +0x288
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Goroutine 184 (running) created at:
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net.TestProlongTimeout()
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src/net/timeout_test.go:618 +0x298
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testing.tRunner()
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src/testing/testing.go:301 +0xe8
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</pre>
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<h2 id="Options">Options</h2>
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<p>
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The <code>GORACE</code> environment variable sets race detector options.
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The format is:
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</p>
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<pre>
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GORACE="option1=val1 option2=val2"
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</pre>
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<p>
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The options are:
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</p>
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<ul>
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<li>
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<code>log_path</code> (default <code>stderr</code>): The race detector writes
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its report to a file named <code>log_path.<em>pid</em></code>.
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The special names <code>stdout</code>
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and <code>stderr</code> cause reports to be written to standard output and
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standard error, respectively.
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</li>
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<li>
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<code>exitcode</code> (default <code>66</code>): The exit status to use when
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exiting after a detected race.
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</li>
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<li>
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<code>strip_path_prefix</code> (default <code>""</code>): Strip this prefix
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from all reported file paths, to make reports more concise.
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</li>
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<li>
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<code>history_size</code> (default <code>1</code>): The per-goroutine memory
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access history is <code>32K * 2**history_size elements</code>.
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Increasing this value can avoid a "failed to restore the stack" error in reports, at the
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cost of increased memory usage.
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</li>
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<li>
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<code>halt_on_error</code> (default <code>0</code>): Controls whether the program
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exits after reporting first data race.
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</li>
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<li>
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<code>atexit_sleep_ms</code> (default <code>1000</code>): Amount of milliseconds
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to sleep in the main goroutine before exiting.
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</li>
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</ul>
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<p>
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Example:
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</p>
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<pre>
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$ GORACE="log_path=/tmp/race/report strip_path_prefix=/my/go/sources/" go test -race
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</pre>
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<h2 id="Excluding_Tests">Excluding Tests</h2>
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<p>
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When you build with <code>-race</code> flag, the <code>go</code> command defines additional
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<a href="/pkg/go/build/#hdr-Build_Constraints">build tag</a> <code>race</code>.
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You can use the tag to exclude some code and tests when running the race detector.
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Some examples:
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</p>
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<pre>
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// +build !race
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package foo
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// The test contains a data race. See issue 123.
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func TestFoo(t *testing.T) {
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// ...
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}
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// The test fails under the race detector due to timeouts.
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func TestBar(t *testing.T) {
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// ...
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}
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// The test takes too long under the race detector.
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func TestBaz(t *testing.T) {
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// ...
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}
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</pre>
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<h2 id="How_To_Use">How To Use</h2>
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<p>
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To start, run your tests using the race detector (<code>go test -race</code>).
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The race detector only finds races that happen at runtime, so it can't find
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races in code paths that are not executed.
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If your tests have incomplete coverage,
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you may find more races by running a binary built with <code>-race</code> under a realistic
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workload.
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</p>
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<h2 id="Typical_Data_Races">Typical Data Races</h2>
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<p>
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Here are some typical data races. All of them can be detected with the race detector.
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</p>
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<h3 id="Race_on_loop_counter">Race on loop counter</h3>
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<pre>
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func main() {
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var wg sync.WaitGroup
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wg.Add(5)
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for i := 0; i < 5; i++ {
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go func() {
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fmt.Println(i) // Not the 'i' you are looking for.
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wg.Done()
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}()
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}
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wg.Wait()
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}
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</pre>
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<p>
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The variable <code>i</code> in the function literal is the same variable used by the loop, so
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the read in the goroutine races with the loop increment.
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(This program typically prints 55555, not 01234.)
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The program can be fixed by making a copy of the variable:
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</p>
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<pre>
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func main() {
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var wg sync.WaitGroup
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wg.Add(5)
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for i := 0; i < 5; i++ {
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go func(j int) {
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fmt.Println(j) // Good. Read local copy of the loop counter.
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wg.Done()
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}(i)
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}
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wg.Wait()
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}
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</pre>
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<h3 id="Accidentally_shared_variable">Accidentally shared variable</h3>
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<pre>
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// ParallelWrite writes data to file1 and file2, returns the errors.
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func ParallelWrite(data []byte) chan error {
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res := make(chan error, 2)
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f1, err := os.Create("file1")
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if err != nil {
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res <- err
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} else {
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go func() {
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// This err is shared with the main goroutine,
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// so the write races with the write below.
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_, err = f1.Write(data)
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res <- err
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f1.Close()
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}()
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}
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f2, err := os.Create("file2") // The second conflicting write to err.
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if err != nil {
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res <- err
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} else {
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go func() {
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_, err = f2.Write(data)
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res <- err
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f2.Close()
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}()
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}
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return res
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}
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</pre>
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<p>
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The fix is to introduce new variables in the goroutines (note the use of <code>:=</code>):
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</p>
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<pre>
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...
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_, err := f1.Write(data)
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...
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_, err := f2.Write(data)
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...
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</pre>
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<h3 id="Unprotected_global_variable">Unprotected global variable</h3>
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<p>
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If the following code is called from several goroutines, it leads to races on the <code>service</code> map.
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Concurrent reads and writes of the same map are not safe:
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</p>
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<pre>
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var service map[string]net.Addr
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func RegisterService(name string, addr net.Addr) {
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service[name] = addr
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}
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func LookupService(name string) net.Addr {
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return service[name]
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}
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</pre>
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<p>
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To make the code safe, protect the accesses with a mutex:
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</p>
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<pre>
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var (
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service map[string]net.Addr
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serviceMu sync.Mutex
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)
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func RegisterService(name string, addr net.Addr) {
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serviceMu.Lock()
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defer serviceMu.Unlock()
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service[name] = addr
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}
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func LookupService(name string) net.Addr {
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serviceMu.Lock()
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defer serviceMu.Unlock()
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return service[name]
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}
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</pre>
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<h3 id="Primitive_unprotected_variable">Primitive unprotected variable</h3>
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<p>
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Data races can happen on variables of primitive types as well (<code>bool</code>, <code>int</code>, <code>int64</code>, etc.),
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as in this example:
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</p>
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<pre>
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type Watchdog struct{ last int64 }
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func (w *Watchdog) KeepAlive() {
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w.last = time.Now().UnixNano() // First conflicting access.
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}
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func (w *Watchdog) Start() {
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go func() {
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for {
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time.Sleep(time.Second)
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// Second conflicting access.
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if w.last < time.Now().Add(-10*time.Second).UnixNano() {
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fmt.Println("No keepalives for 10 seconds. Dying.")
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os.Exit(1)
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}
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}
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}()
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}
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</pre>
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<p>
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Even such "innocent" data races can lead to hard-to-debug problems caused by
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non-atomicity of the memory accesses,
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interference with compiler optimizations,
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or reordering issues accessing processor memory .
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</p>
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<p>
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A typical fix for this race is to use a channel or a mutex.
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To preserve the lock-free behavior, one can also use the
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<a href="/pkg/sync/atomic/"><code>sync/atomic</code></a> package.
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</p>
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<pre>
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type Watchdog struct{ last int64 }
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func (w *Watchdog) KeepAlive() {
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atomic.StoreInt64(&w.last, time.Now().UnixNano())
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}
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func (w *Watchdog) Start() {
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go func() {
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for {
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time.Sleep(time.Second)
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if atomic.LoadInt64(&w.last) < time.Now().Add(-10*time.Second).UnixNano() {
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fmt.Println("No keepalives for 10 seconds. Dying.")
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os.Exit(1)
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}
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}
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}()
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}
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</pre>
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<h3 id="Unsynchronized_send_and_close_operations">Unsynchronized send and close operations</h3>
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<p>
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As this example demonstrates, unsynchronized send and close operations
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on the same channel can also be a race condition:
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</p>
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<pre>
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c := make(chan struct{}) // or buffered channel
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// The race detector cannot derive the happens before relation
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// for the following send and close operations. These two operations
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// are unsynchronized and happen concurrently.
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go func() { c <- struct{}{} }()
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close(c)
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</pre>
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<p>
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According to the Go memory model, a send on a channel happens before
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the corresponding receive from that channel completes. To synchronize
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send and close operations, use a receive operation that guarantees
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the send is done before the close:
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</p>
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<pre>
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c := make(chan struct{}) // or buffered channel
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go func() { c <- struct{}{} }()
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<-c
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close(c)
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</pre>
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<h2 id="Supported_Systems">Supported Systems</h2>
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<p>
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The race detector runs on
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<code>linux/amd64</code>, <code>linux/ppc64le</code>,
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<code>linux/arm64</code>, <code>freebsd/amd64</code>,
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<code>netbsd/amd64</code>, <code>darwin/amd64</code>,
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<code>darwin/arm64</code>, and <code>windows/amd64</code>.
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</p>
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<h2 id="Runtime_Overheads">Runtime Overhead</h2>
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<p>
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The cost of race detection varies by program, but for a typical program, memory
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usage may increase by 5-10x and execution time by 2-20x.
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</p>
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<p>
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The race detector currently allocates an extra 8 bytes per <code>defer</code>
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and <code>recover</code> statement. Those extra allocations <a
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href="https://golang.org/issue/26813">are not recovered until the goroutine
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exits</a>. This means that if you have a long-running goroutine that is
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periodically issuing <code>defer</code> and <code>recover</code> calls,
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the program memory usage may grow without bound. These memory allocations
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will not show up in the output of <code>runtime.ReadMemStats</code> or
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<code>runtime/pprof</code>.
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</p>
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