2016-02-22 14:44:12 -05:00
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// The panicwrap package provides functions for capturing and handling
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// panics in your application. It does this by re-executing the running
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// application and monitoring stderr for any panics. At the same time,
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// stdout/stderr/etc. are set to the same values so that data is shuttled
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// through properly, making the existence of panicwrap mostly transparent.
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//
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// Panics are only detected when the subprocess exits with a non-zero
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// exit status, since this is the only time panics are real. Otherwise,
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// "panic-like" output is ignored.
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package panicwrap
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import (
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"bytes"
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"errors"
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"io"
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"os"
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"os/exec"
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"os/signal"
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2017-06-15 04:15:32 -04:00
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"runtime"
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"sync/atomic"
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2016-02-22 14:44:12 -05:00
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"syscall"
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"time"
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2017-06-15 04:15:32 -04:00
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"github.com/kardianos/osext"
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2016-02-22 14:44:12 -05:00
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)
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const (
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DEFAULT_COOKIE_KEY = "cccf35992f8f3cd8d1d28f0109dd953e26664531"
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DEFAULT_COOKIE_VAL = "7c28215aca87789f95b406b8dd91aa5198406750"
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)
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// HandlerFunc is the type called when a panic is detected.
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type HandlerFunc func(string)
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// WrapConfig is the configuration for panicwrap when wrapping an existing
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// binary. To get started, in general, you only need the BasicWrap function
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// that will set this up for you. However, for more customizability,
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// WrapConfig and Wrap can be used.
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type WrapConfig struct {
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// Handler is the function called when a panic occurs.
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Handler HandlerFunc
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// The cookie key and value are used within environmental variables
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// to tell the child process that it is already executing so that
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// wrap doesn't re-wrap itself.
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CookieKey string
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CookieValue string
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// If true, the panic will not be mirrored to the configured writer
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// and will instead ONLY go to the handler. This lets you effectively
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// hide panics from the end user. This is not recommended because if
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// your handler fails, the panic is effectively lost.
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HidePanic bool
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// The amount of time that a process must exit within after detecting
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// a panic header for panicwrap to assume it is a panic. Defaults to
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// 300 milliseconds.
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DetectDuration time.Duration
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// The writer to send the stderr to. If this is nil, then it defaults
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// to os.Stderr.
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Writer io.Writer
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// The writer to send stdout to. If this is nil, then it defaults to
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// os.Stdout.
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Stdout io.Writer
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// Catch and igore these signals in the parent process, let the child
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// handle them gracefully.
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IgnoreSignals []os.Signal
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// Catch these signals in the parent process and manually forward
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// them to the child process. Some signals such as SIGINT are usually
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// sent to the entire process group so setting it isn't necessary. Other
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// signals like SIGTERM are only sent to the parent process and need
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// to be forwarded. This defaults to empty.
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ForwardSignals []os.Signal
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2016-02-22 14:44:12 -05:00
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}
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// BasicWrap calls Wrap with the given handler function, using defaults
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// for everything else. See Wrap and WrapConfig for more information on
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// functionality and return values.
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func BasicWrap(f HandlerFunc) (int, error) {
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return Wrap(&WrapConfig{
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Handler: f,
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})
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}
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// Wrap wraps the current executable in a handler to catch panics. It
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// returns an error if there was an error during the wrapping process.
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// If the error is nil, then the int result indicates the exit status of the
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// child process. If the exit status is -1, then this is the child process,
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// and execution should continue as normal. Otherwise, this is the parent
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// process and the child successfully ran already, and you should exit the
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// process with the returned exit status.
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//
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// This function should be called very very early in your program's execution.
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// Ideally, this runs as the first line of code of main.
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//
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// Once this is called, the given WrapConfig shouldn't be modified or used
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// any further.
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func Wrap(c *WrapConfig) (int, error) {
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if c.Handler == nil {
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return -1, errors.New("Handler must be set")
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}
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if c.DetectDuration == 0 {
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c.DetectDuration = 300 * time.Millisecond
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}
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if c.Writer == nil {
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c.Writer = os.Stderr
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}
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// If we're already wrapped, exit out.
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if Wrapped(c) {
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return -1, nil
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}
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// Get the path to our current executable
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exePath, err := osext.Executable()
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if err != nil {
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return -1, err
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}
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// Pipe the stderr so we can read all the data as we look for panics
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stderr_r, stderr_w := io.Pipe()
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// doneCh is closed when we're done, signaling any other goroutines
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// to end immediately.
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doneCh := make(chan struct{})
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// panicCh is the channel on which the panic text will actually be
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// sent.
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panicCh := make(chan string)
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// On close, make sure to finish off the copying of data to stderr
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defer func() {
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defer close(doneCh)
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stderr_w.Close()
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<-panicCh
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}()
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// Start the goroutine that will watch stderr for any panics
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go trackPanic(stderr_r, c.Writer, c.DetectDuration, panicCh)
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// Create the writer for stdout that we're going to use
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var stdout_w io.Writer = os.Stdout
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if c.Stdout != nil {
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stdout_w = c.Stdout
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}
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// Build a subcommand to re-execute ourselves. We make sure to
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// set the environmental variable to include our cookie. We also
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// set stdin/stdout to match the config. Finally, we pipe stderr
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// through ourselves in order to watch for panics.
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cmd := exec.Command(exePath, os.Args[1:]...)
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cmd.Env = append(os.Environ(), c.CookieKey+"="+c.CookieValue)
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cmd.Stdin = os.Stdin
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cmd.Stdout = stdout_w
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cmd.Stderr = stderr_w
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// Windows doesn't support this, but on other platforms pass in
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// the original file descriptors so they can be used.
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if runtime.GOOS != "windows" {
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cmd.ExtraFiles = []*os.File{os.Stdin, os.Stdout, os.Stderr}
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}
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2016-02-22 14:44:12 -05:00
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if err := cmd.Start(); err != nil {
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return 1, err
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}
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// Listen to signals and capture them forever. We allow the child
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// process to handle them in some way.
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sigCh := make(chan os.Signal)
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fwdSigCh := make(chan os.Signal)
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if len(c.IgnoreSignals) == 0 {
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c.IgnoreSignals = []os.Signal{os.Interrupt}
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}
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signal.Notify(sigCh, c.IgnoreSignals...)
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signal.Notify(fwdSigCh, c.ForwardSignals...)
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go func() {
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defer signal.Stop(sigCh)
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defer signal.Stop(fwdSigCh)
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2016-02-22 14:44:12 -05:00
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for {
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select {
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case <-doneCh:
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return
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case s := <-fwdSigCh:
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if cmd.Process != nil {
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cmd.Process.Signal(s)
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}
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2016-02-22 14:44:12 -05:00
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case <-sigCh:
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}
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}
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}()
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if err := cmd.Wait(); err != nil {
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exitErr, ok := err.(*exec.ExitError)
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if !ok {
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// This is some other kind of subprocessing error.
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return 1, err
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}
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exitStatus := 1
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if status, ok := exitErr.Sys().(syscall.WaitStatus); ok {
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exitStatus = status.ExitStatus()
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}
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// Close the writer end so that the tracker goroutine ends at some point
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stderr_w.Close()
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// Wait on the panic data
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panicTxt := <-panicCh
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if panicTxt != "" {
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if !c.HidePanic {
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c.Writer.Write([]byte(panicTxt))
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}
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c.Handler(panicTxt)
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}
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return exitStatus, nil
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}
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return 0, nil
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}
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// Wrapped checks if we're already wrapped according to the configuration
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// given.
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//
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// Wrapped is very cheap and can be used early to short-circuit some pre-wrap
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// logic your application may have.
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2017-06-15 04:15:32 -04:00
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//
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// If the given configuration is nil, then this will return a cached
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// value of Wrapped. This is useful because Wrapped is usually called early
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// to verify a process hasn't been wrapped before wrapping. After this,
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// the value of Wrapped hardly changes and is process-global, so other
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// libraries can check with Wrapped(nil).
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2016-02-22 14:44:12 -05:00
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func Wrapped(c *WrapConfig) bool {
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if c == nil {
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return wrapCache.Load().(bool)
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}
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2016-02-22 14:44:12 -05:00
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if c.CookieKey == "" {
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c.CookieKey = DEFAULT_COOKIE_KEY
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}
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if c.CookieValue == "" {
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c.CookieValue = DEFAULT_COOKIE_VAL
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}
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// If the cookie key/value match our environment, then we are the
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// child, so just exit now and tell the caller that we're the child
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2017-06-15 04:15:32 -04:00
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result := os.Getenv(c.CookieKey) == c.CookieValue
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wrapCache.Store(result)
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return result
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}
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// wrapCache is the cached value for Wrapped when called with nil
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var wrapCache atomic.Value
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func init() {
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wrapCache.Store(false)
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2016-02-22 14:44:12 -05:00
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}
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// trackPanic monitors the given reader for a panic. If a panic is detected,
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// it is outputted on the result channel. This will close the channel once
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// it is complete.
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func trackPanic(r io.Reader, w io.Writer, dur time.Duration, result chan<- string) {
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defer close(result)
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var panicTimer <-chan time.Time
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panicBuf := new(bytes.Buffer)
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panicHeaders := [][]byte{
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[]byte("panic:"),
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[]byte("fatal error: fault"),
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}
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panicType := -1
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tempBuf := make([]byte, 2048)
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for {
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var buf []byte
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var n int
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if panicTimer == nil && panicBuf.Len() > 0 {
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// We're not tracking a panic but the buffer length is
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// greater than 0. We need to clear out that buffer, but
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// look for another panic along the way.
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// First, remove the previous panic header so we don't loop
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w.Write(panicBuf.Next(len(panicHeaders[panicType])))
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// Next, assume that this is our new buffer to inspect
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n = panicBuf.Len()
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buf = make([]byte, n)
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copy(buf, panicBuf.Bytes())
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panicBuf.Reset()
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} else {
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var err error
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buf = tempBuf
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n, err = r.Read(buf)
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if n <= 0 && err == io.EOF {
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if panicBuf.Len() > 0 {
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// We were tracking a panic, assume it was a panic
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// and return that as the result.
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result <- panicBuf.String()
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}
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return
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}
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}
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if panicTimer != nil {
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// We're tracking what we think is a panic right now.
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// If the timer ended, then it is not a panic.
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isPanic := true
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select {
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case <-panicTimer:
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isPanic = false
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default:
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}
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// No matter what, buffer the text some more.
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panicBuf.Write(buf[0:n])
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if !isPanic {
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// It isn't a panic, stop tracking. Clean-up will happen
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// on the next iteration.
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panicTimer = nil
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}
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continue
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}
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panicType = -1
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flushIdx := n
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for i, header := range panicHeaders {
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idx := bytes.Index(buf[0:n], header)
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if idx >= 0 {
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panicType = i
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flushIdx = idx
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break
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}
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}
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// Flush to stderr what isn't a panic
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w.Write(buf[0:flushIdx])
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if panicType == -1 {
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// Not a panic so just continue along
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continue
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}
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// We have a panic header. Write we assume is a panic os far.
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panicBuf.Write(buf[flushIdx:n])
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panicTimer = time.After(dur)
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}
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}
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