open-nomad/command/logs.go

291 lines
6.7 KiB
Go

package command
import (
"fmt"
"io"
"os"
"os/signal"
"strings"
"syscall"
"time"
"github.com/hashicorp/nomad/api"
"github.com/hashicorp/nomad/api/contexts"
"github.com/posener/complete"
)
type LogsCommand struct {
Meta
}
func (l *LogsCommand) Help() string {
helpText := `
Usage: nomad logs [options] <allocation> <task>
Streams the stdout/stderr of the given allocation and task.
General Options:
` + generalOptionsUsage() + `
Logs Specific Options:
-stderr
Display stderr logs.
-verbose
Show full information.
-job <job-id>
Use a random allocation from the specified job ID.
-f
Causes the output to not stop when the end of the logs are reached, but
rather to wait for additional output.
-tail
Show the logs contents with offsets relative to the end of the logs. If no
offset is given, -n is defaulted to 10.
-n
Sets the tail location in best-efforted number of lines relative to the end
of the logs.
-c
Sets the tail location in number of bytes relative to the end of the logs.
`
return strings.TrimSpace(helpText)
}
func (l *LogsCommand) Synopsis() string {
return "Streams the logs of a task."
}
func (c *LogsCommand) AutocompleteFlags() complete.Flags {
return mergeAutocompleteFlags(c.Meta.AutocompleteFlags(FlagSetClient),
complete.Flags{
"-stderr": complete.PredictNothing,
"-verbose": complete.PredictNothing,
"-job": complete.PredictAnything,
"-f": complete.PredictNothing,
"-tail": complete.PredictAnything,
"-n": complete.PredictAnything,
"-c": complete.PredictAnything,
})
}
func (l *LogsCommand) AutocompleteArgs() complete.Predictor {
client, _ := l.Meta.Client()
return complete.PredictFunc(func(a complete.Args) []string {
if len(a.Completed) > 1 {
return nil
}
resp, _, err := client.Search().PrefixSearch(a.Last, contexts.Allocs, nil)
if err != nil {
return []string{}
}
return resp.Matches[contexts.Allocs]
})
}
func (l *LogsCommand) Run(args []string) int {
var verbose, job, tail, stderr, follow bool
var numLines, numBytes int64
flags := l.Meta.FlagSet("logs", FlagSetClient)
flags.Usage = func() { l.Ui.Output(l.Help()) }
flags.BoolVar(&verbose, "verbose", false, "")
flags.BoolVar(&job, "job", false, "")
flags.BoolVar(&tail, "tail", false, "")
flags.BoolVar(&follow, "f", false, "")
flags.BoolVar(&stderr, "stderr", false, "")
flags.Int64Var(&numLines, "n", -1, "")
flags.Int64Var(&numBytes, "c", -1, "")
if err := flags.Parse(args); err != nil {
return 1
}
args = flags.Args()
if numArgs := len(args); numArgs < 1 {
if job {
l.Ui.Error("Job ID required. See help:\n")
} else {
l.Ui.Error("Allocation ID required. See help:\n")
}
l.Ui.Error(l.Help())
return 1
} else if numArgs > 2 {
l.Ui.Error(l.Help())
return 1
}
client, err := l.Meta.Client()
if err != nil {
l.Ui.Error(fmt.Sprintf("Error initializing client: %v", err))
return 1
}
// If -job is specified, use random allocation, otherwise use provided allocation
allocID := args[0]
if job {
allocID, err = getRandomJobAlloc(client, args[0])
if err != nil {
l.Ui.Error(fmt.Sprintf("Error fetching allocations: %v", err))
return 1
}
}
// Truncate the id unless full length is requested
length := shortId
if verbose {
length = fullId
}
// Query the allocation info
if len(allocID) == 1 {
l.Ui.Error(fmt.Sprintf("Alloc ID must contain at least two characters."))
return 1
}
if len(allocID)%2 == 1 {
// Identifiers must be of even length, so we strip off the last byte
// to provide a consistent user experience.
allocID = allocID[:len(allocID)-1]
}
allocs, _, err := client.Allocations().PrefixList(allocID)
if err != nil {
l.Ui.Error(fmt.Sprintf("Error querying allocation: %v", err))
return 1
}
if len(allocs) == 0 {
l.Ui.Error(fmt.Sprintf("No allocation(s) with prefix or id %q found", allocID))
return 1
}
if len(allocs) > 1 {
// Format the allocs
out := formatAllocListStubs(allocs, verbose, length)
l.Ui.Error(fmt.Sprintf("Prefix matched multiple allocations\n\n%s", out))
return 1
}
// Prefix lookup matched a single allocation
alloc, _, err := client.Allocations().Info(allocs[0].ID, nil)
if err != nil {
l.Ui.Error(fmt.Sprintf("Error querying allocation: %s", err))
return 1
}
var task string
if len(args) >= 2 {
task = args[1]
if task == "" {
l.Ui.Error("Task name required")
return 1
}
} else {
// Try to determine the tasks name from the allocation
var tasks []*api.Task
for _, tg := range alloc.Job.TaskGroups {
if *tg.Name == alloc.TaskGroup {
if len(tg.Tasks) == 1 {
task = tg.Tasks[0].Name
break
}
tasks = tg.Tasks
break
}
}
if task == "" {
l.Ui.Error(fmt.Sprintf("Allocation %q is running the following tasks:", limit(alloc.ID, length)))
for _, t := range tasks {
l.Ui.Error(fmt.Sprintf(" * %s", t.Name))
}
l.Ui.Error("\nPlease specify the task.")
return 1
}
}
logType := "stdout"
if stderr {
logType = "stderr"
}
// We have a file, output it.
var r io.ReadCloser
var readErr error
if !tail {
r, readErr = l.followFile(client, alloc, follow, task, logType, api.OriginStart, 0)
if readErr != nil {
readErr = fmt.Errorf("Error reading file: %v", readErr)
}
} else {
// Parse the offset
var offset int64 = defaultTailLines * bytesToLines
if nLines, nBytes := numLines != -1, numBytes != -1; nLines && nBytes {
l.Ui.Error("Both -n and -c set")
return 1
} else if nLines {
offset = numLines * bytesToLines
} else if nBytes {
offset = numBytes
} else {
numLines = defaultTailLines
}
r, readErr = l.followFile(client, alloc, follow, task, logType, api.OriginEnd, offset)
// If numLines is set, wrap the reader
if numLines != -1 {
r = NewLineLimitReader(r, int(numLines), int(numLines*bytesToLines), 1*time.Second)
}
if readErr != nil {
readErr = fmt.Errorf("Error tailing file: %v", readErr)
}
}
if readErr != nil {
l.Ui.Error(readErr.Error())
return 1
}
defer r.Close()
io.Copy(os.Stdout, r)
return 0
}
// followFile outputs the contents of the file to stdout relative to the end of
// the file.
func (l *LogsCommand) followFile(client *api.Client, alloc *api.Allocation,
follow bool, task, logType, origin string, offset int64) (io.ReadCloser, error) {
cancel := make(chan struct{})
frames, err := client.AllocFS().Logs(alloc, follow, task, logType, origin, offset, cancel, nil)
if err != nil {
return nil, err
}
signalCh := make(chan os.Signal, 1)
signal.Notify(signalCh, os.Interrupt, syscall.SIGTERM)
// Create a reader
var r io.ReadCloser
frameReader := api.NewFrameReader(frames, cancel)
frameReader.SetUnblockTime(500 * time.Millisecond)
r = frameReader
go func() {
<-signalCh
// End the streaming
r.Close()
}()
return r, nil
}