package command import ( "bufio" "bytes" "encoding/json" "fmt" "io" "os" "path/filepath" "strconv" "strings" "time" gg "github.com/hashicorp/go-getter" "github.com/hashicorp/nomad/api" flaghelper "github.com/hashicorp/nomad/helper/flags" "github.com/hashicorp/nomad/jobspec" "github.com/hashicorp/nomad/jobspec2" "github.com/kr/text" "github.com/mitchellh/cli" "github.com/posener/complete" "github.com/ryanuber/columnize" ) // maxLineLength is the maximum width of any line. const maxLineLength int = 78 // formatKV takes a set of strings and formats them into properly // aligned k = v pairs using the columnize library. func formatKV(in []string) string { columnConf := columnize.DefaultConfig() columnConf.Empty = "" columnConf.Glue = " = " return columnize.Format(in, columnConf) } // formatList takes a set of strings and formats them into properly // aligned output, replacing any blank fields with a placeholder // for awk-ability. func formatList(in []string) string { columnConf := columnize.DefaultConfig() columnConf.Empty = "" return columnize.Format(in, columnConf) } // formatListWithSpaces takes a set of strings and formats them into properly // aligned output. It should be used sparingly since it doesn't replace empty // values and hence not awk/sed friendly func formatListWithSpaces(in []string) string { columnConf := columnize.DefaultConfig() return columnize.Format(in, columnConf) } // Limits the length of the string. func limit(s string, length int) string { if len(s) < length { return s } return s[:length] } // wrapAtLengthWithPadding wraps the given text at the maxLineLength, taking // into account any provided left padding. func wrapAtLengthWithPadding(s string, pad int) string { wrapped := text.Wrap(s, maxLineLength-pad) lines := strings.Split(wrapped, "\n") for i, line := range lines { lines[i] = strings.Repeat(" ", pad) + line } return strings.Join(lines, "\n") } // wrapAtLength wraps the given text to maxLineLength. func wrapAtLength(s string) string { return wrapAtLengthWithPadding(s, 0) } // formatTime formats the time to string based on RFC822 func formatTime(t time.Time) string { if t.Unix() < 1 { // It's more confusing to display the UNIX epoch or a zero value than nothing return "" } // Return ISO_8601 time format GH-3806 return t.Format("2006-01-02T15:04:05Z07:00") } // formatUnixNanoTime is a helper for formatting time for output. func formatUnixNanoTime(nano int64) string { t := time.Unix(0, nano) return formatTime(t) } // formatTimeDifference takes two times and determines their duration difference // truncating to a passed unit. // E.g. formatTimeDifference(first=1m22s33ms, second=1m28s55ms, time.Second) -> 6s func formatTimeDifference(first, second time.Time, d time.Duration) string { return second.Truncate(d).Sub(first.Truncate(d)).String() } // fmtInt formats v into the tail of buf. // It returns the index where the output begins. func fmtInt(buf []byte, v uint64) int { w := len(buf) for v > 0 { w-- buf[w] = byte(v%10) + '0' v /= 10 } return w } // prettyTimeDiff prints a human readable time difference. // It uses abbreviated forms for each period - s for seconds, m for minutes, h for hours, // d for days, mo for months, and y for years. Time difference is rounded to the nearest second, // and the top two least granular periods are returned. For example, if the time difference // is 10 months, 12 days, 3 hours and 2 seconds, the string "10mo12d" is returned. Zero values return the empty string func prettyTimeDiff(first, second time.Time) string { // handle zero values if first.IsZero() || first.UnixNano() == 0 { return "" } // round to the nearest second first = first.Round(time.Second) second = second.Round(time.Second) // calculate time difference in seconds var d time.Duration messageSuffix := "ago" if second.Equal(first) || second.After(first) { d = second.Sub(first) } else { d = first.Sub(second) messageSuffix = "from now" } u := uint64(d.Seconds()) var buf [32]byte w := len(buf) secs := u % 60 // track indexes of various periods var indexes []int if secs > 0 { w-- buf[w] = 's' // u is now seconds w = fmtInt(buf[:w], secs) indexes = append(indexes, w) } u /= 60 // u is now minutes if u > 0 { mins := u % 60 if mins > 0 { w-- buf[w] = 'm' w = fmtInt(buf[:w], mins) indexes = append(indexes, w) } u /= 60 // u is now hours if u > 0 { hrs := u % 24 if hrs > 0 { w-- buf[w] = 'h' w = fmtInt(buf[:w], hrs) indexes = append(indexes, w) } u /= 24 } // u is now days if u > 0 { days := u % 30 if days > 0 { w-- buf[w] = 'd' w = fmtInt(buf[:w], days) indexes = append(indexes, w) } u /= 30 } // u is now months if u > 0 { months := u % 12 if months > 0 { w-- buf[w] = 'o' w-- buf[w] = 'm' w = fmtInt(buf[:w], months) indexes = append(indexes, w) } u /= 12 } // u is now years if u > 0 { w-- buf[w] = 'y' w = fmtInt(buf[:w], u) indexes = append(indexes, w) } } start := w end := len(buf) // truncate to the first two periods num_periods := len(indexes) if num_periods > 2 { end = indexes[num_periods-3] } if start == end { //edge case when time difference is less than a second return "0s " + messageSuffix } else { return string(buf[start:end]) + " " + messageSuffix } } // getLocalNodeID returns the node ID of the local Nomad Client and an error if // it couldn't be determined or the Agent is not running in Client mode. func getLocalNodeID(client *api.Client) (string, error) { info, err := client.Agent().Self() if err != nil { return "", fmt.Errorf("Error querying agent info: %s", err) } clientStats, ok := info.Stats["client"] if !ok { return "", fmt.Errorf("Nomad not running in client mode") } nodeID, ok := clientStats["node_id"] if !ok { return "", fmt.Errorf("Failed to determine node ID") } return nodeID, nil } // evalFailureStatus returns whether the evaluation has failures and a string to // display when presenting users with whether there are failures for the eval func evalFailureStatus(eval *api.Evaluation) (string, bool) { if eval == nil { return "", false } hasFailures := len(eval.FailedTGAllocs) != 0 text := strconv.FormatBool(hasFailures) if eval.Status == "blocked" { text = "N/A - In Progress" } return text, hasFailures } // LineLimitReader wraps another reader and provides `tail -n` like behavior. // LineLimitReader buffers up to the searchLimit and returns `-n` number of // lines. After those lines have been returned, LineLimitReader streams the // underlying ReadCloser type LineLimitReader struct { io.ReadCloser lines int searchLimit int timeLimit time.Duration lastRead time.Time buffer *bytes.Buffer bufFiled bool foundLines bool } // NewLineLimitReader takes the ReadCloser to wrap, the number of lines to find // searching backwards in the first searchLimit bytes. timeLimit can optionally // be specified by passing a non-zero duration. When set, the search for the // last n lines is aborted if no data has been read in the duration. This // can be used to flush what is had if no extra data is being received. When // used, the underlying reader must not block forever and must periodically // unblock even when no data has been read. func NewLineLimitReader(r io.ReadCloser, lines, searchLimit int, timeLimit time.Duration) *LineLimitReader { return &LineLimitReader{ ReadCloser: r, searchLimit: searchLimit, timeLimit: timeLimit, lines: lines, buffer: bytes.NewBuffer(make([]byte, 0, searchLimit)), } } func (l *LineLimitReader) Read(p []byte) (n int, err error) { // Fill up the buffer so we can find the correct number of lines. if !l.bufFiled { b := make([]byte, len(p)) n, err := l.ReadCloser.Read(b) if n > 0 { if _, err := l.buffer.Write(b[:n]); err != nil { return 0, err } } if err != nil { if err != io.EOF { return 0, err } l.bufFiled = true goto READ } if l.buffer.Len() >= l.searchLimit { l.bufFiled = true goto READ } if l.timeLimit.Nanoseconds() > 0 { if l.lastRead.IsZero() { l.lastRead = time.Now() return 0, nil } now := time.Now() if n == 0 { // We hit the limit if l.lastRead.Add(l.timeLimit).Before(now) { l.bufFiled = true goto READ } else { return 0, nil } } else { l.lastRead = now } } return 0, nil } READ: if l.bufFiled && l.buffer.Len() != 0 { b := l.buffer.Bytes() // Find the lines if !l.foundLines { found := 0 i := len(b) - 1 sep := byte('\n') lastIndex := len(b) - 1 for ; found < l.lines && i >= 0; i-- { if b[i] == sep { lastIndex = i // Skip the first one if i != len(b)-1 { found++ } } } // We found them all if found == l.lines { // Clear the buffer until the last index l.buffer.Next(lastIndex + 1) } l.foundLines = true } // Read from the buffer n := copy(p, l.buffer.Next(len(p))) return n, nil } // Just stream from the underlying reader now return l.ReadCloser.Read(p) } // JobGetter provides helpers for retrieving and parsing a jobpsec. type JobGetter struct { HCL1 bool Vars flaghelper.StringFlag VarFiles flaghelper.StringFlag Strict bool JSON bool // The fields below can be overwritten for tests testStdin io.Reader } func (j *JobGetter) Validate() error { if j.HCL1 && j.Strict { return fmt.Errorf("cannot parse job file as HCLv1 and HCLv2 strict.") } if j.HCL1 && j.JSON { return fmt.Errorf("cannot parse job file as HCL and JSON.") } if len(j.Vars) > 0 && j.JSON { return fmt.Errorf("cannot use variables with JSON files.") } if len(j.VarFiles) > 0 && j.JSON { return fmt.Errorf("cannot use variables with JSON files.") } if len(j.Vars) > 0 && j.HCL1 { return fmt.Errorf("cannot use variables with HCLv1.") } if len(j.VarFiles) > 0 && j.HCL1 { return fmt.Errorf("cannot use variables with HCLv1.") } return nil } // ApiJob returns the Job struct from jobfile. func (j *JobGetter) ApiJob(jpath string) (*api.Job, error) { return j.ApiJobWithArgs(jpath, nil, nil, true) } func (j *JobGetter) ApiJobWithArgs(jpath string, vars []string, varfiles []string, strict bool) (*api.Job, error) { j.Vars = vars j.VarFiles = varfiles j.Strict = strict return j.Get(jpath) } func (j *JobGetter) Get(jpath string) (*api.Job, error) { var jobfile io.Reader pathName := filepath.Base(jpath) switch jpath { case "-": if j.testStdin != nil { jobfile = j.testStdin } else { jobfile = os.Stdin } pathName = "stdin" default: if len(jpath) == 0 { return nil, fmt.Errorf("Error jobfile path has to be specified.") } jobFile, err := os.CreateTemp("", "jobfile") if err != nil { return nil, err } defer os.Remove(jobFile.Name()) if err := jobFile.Close(); err != nil { return nil, err } // Get the pwd pwd, err := os.Getwd() if err != nil { return nil, err } client := &gg.Client{ Src: jpath, Pwd: pwd, Dst: jobFile.Name(), // This will prevent copying or writing files through symlinks DisableSymlinks: true, } if err := client.Get(); err != nil { return nil, fmt.Errorf("Error getting jobfile from %q: %v", jpath, err) } else { file, err := os.Open(jobFile.Name()) if err != nil { return nil, fmt.Errorf("Error opening file %q: %v", jpath, err) } defer file.Close() jobfile = file } } // Parse the JobFile var jobStruct *api.Job var err error switch { case j.HCL1: jobStruct, err = jobspec.Parse(jobfile) case j.JSON: // Support JSON files with both a top-level Job key as well as // ones without. eitherJob := struct { NestedJob *api.Job `json:"Job"` api.Job }{} if err := json.NewDecoder(jobfile).Decode(&eitherJob); err != nil { return nil, fmt.Errorf("Failed to parse JSON job: %w", err) } if eitherJob.NestedJob != nil { jobStruct = eitherJob.NestedJob } else { jobStruct = &eitherJob.Job } default: var buf bytes.Buffer _, err = io.Copy(&buf, jobfile) if err != nil { return nil, fmt.Errorf("Error reading job file from %s: %v", jpath, err) } jobStruct, err = jobspec2.ParseWithConfig(&jobspec2.ParseConfig{ Path: pathName, Body: buf.Bytes(), ArgVars: j.Vars, AllowFS: true, VarFiles: j.VarFiles, Envs: os.Environ(), Strict: j.Strict, }) if err != nil { if _, merr := jobspec.Parse(&buf); merr == nil { return nil, fmt.Errorf("Failed to parse using HCL 2. Use the HCL 1 parser with `nomad run -hcl1`, or address the following issues:\n%v", err) } } } if err != nil { return nil, fmt.Errorf("Error parsing job file from %s:\n%v", jpath, err) } return jobStruct, nil } // mergeAutocompleteFlags is used to join multiple flag completion sets. func mergeAutocompleteFlags(flags ...complete.Flags) complete.Flags { merged := make(map[string]complete.Predictor, len(flags)) for _, f := range flags { for k, v := range f { merged[k] = v } } return merged } // sanitizeUUIDPrefix is used to sanitize a UUID prefix. The returned result // will be a truncated version of the prefix if the prefix would not be // queryable. func sanitizeUUIDPrefix(prefix string) string { hyphens := strings.Count(prefix, "-") length := len(prefix) - hyphens remainder := length % 2 return prefix[:len(prefix)-remainder] } // commandErrorText is used to easily render the same messaging across commads // when an error is printed. func commandErrorText(cmd NamedCommand) string { return fmt.Sprintf("For additional help try 'nomad %s -help'", cmd.Name()) } // uiErrorWriter is a io.Writer that wraps underlying ui.ErrorWriter(). // ui.ErrorWriter expects full lines as inputs and it emits its own line breaks. // // uiErrorWriter scans input for individual lines to pass to ui.ErrorWriter. If data // doesn't contain a new line, it buffers result until next new line or writer is closed. type uiErrorWriter struct { ui cli.Ui buf bytes.Buffer } func (w *uiErrorWriter) Write(data []byte) (int, error) { read := 0 for len(data) != 0 { a, token, err := bufio.ScanLines(data, false) if err != nil { return read, err } if a == 0 { r, err := w.buf.Write(data) return read + r, err } w.ui.Error(w.buf.String() + string(token)) data = data[a:] w.buf.Reset() read += a } return read, nil } func (w *uiErrorWriter) Close() error { // emit what's remaining if w.buf.Len() != 0 { w.ui.Error(w.buf.String()) w.buf.Reset() } return nil }