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script.go
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script.go
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package script
import (
"bufio"
"container/ring"
"crypto/sha256"
"encoding/base64"
"encoding/hex"
"encoding/json"
"fmt"
"hash"
"io"
"io/fs"
"math"
"net/http"
"os"
"os/exec"
"path/filepath"
"regexp"
"sort"
"strconv"
"strings"
"sync"
"text/template"
"github.com/itchyny/gojq"
"mvdan.cc/sh/v3/shell"
)
// Pipe represents a pipe object with an associated [ReadAutoCloser].
type Pipe struct {
// Reader is the underlying reader.
Reader ReadAutoCloser
stdout io.Writer
httpClient *http.Client
mu *sync.Mutex
err error
stderr io.Writer
env []string
}
// Args creates a pipe containing the program's command-line arguments from
// [os.Args], excluding the program name, one per line.
func Args() *Pipe {
return Slice(os.Args[1:])
}
// Do creates a pipe that makes the HTTP request req and produces the response.
// See [Pipe.Do] for how the HTTP response status is interpreted.
func Do(req *http.Request) *Pipe {
return NewPipe().Do(req)
}
// Echo creates a pipe containing the string s.
func Echo(s string) *Pipe {
return NewPipe().WithReader(strings.NewReader(s))
}
// Exec creates a pipe that runs cmdLine as an external command and produces
// its combined output (interleaving standard output and standard error). See
// [Pipe.Exec] for error handling details.
//
// Use [Pipe.Exec] to send the contents of an existing pipe to the command's
// standard input.
func Exec(cmdLine string) *Pipe {
return NewPipe().Exec(cmdLine)
}
// File creates a pipe that reads from the file path.
func File(path string) *Pipe {
f, err := os.Open(path)
if err != nil {
return NewPipe().WithError(err)
}
return NewPipe().WithReader(f)
}
// FindFiles creates a pipe listing all the files in the directory dir and its
// subdirectories recursively, one per line, like Unix find(1).
// Errors are ignored unless no files are found (in which case the pipe's error
// status will be set to the last error encountered).
//
// Each line of the output consists of a slash-separated path, starting with
// the initial directory. For example, if the directory looks like this:
//
// test/
// 1.txt
// 2.txt
//
// the pipe's output will be:
//
// test/1.txt
// test/2.txt
func FindFiles(dir string) *Pipe {
var paths []string
var innerErr error
fs.WalkDir(os.DirFS(dir), ".", func(path string, d fs.DirEntry, err error) error {
if err != nil {
innerErr = err
return fs.SkipDir
}
if !d.IsDir() {
paths = append(paths, filepath.Join(dir, path))
}
return nil
})
if innerErr != nil && len(paths) == 0 {
return NewPipe().WithError(innerErr)
}
return Slice(paths)
}
// Get creates a pipe that makes an HTTP GET request to url, and produces the
// response. See [Pipe.Do] for how the HTTP response status is interpreted.
func Get(url string) *Pipe {
return NewPipe().Get(url)
}
// IfExists tests whether path exists, and creates a pipe whose error status
// reflects the result. If the file doesn't exist, the pipe's error status will
// be set, and if the file does exist, the pipe will have no error status. This
// can be used to do some operation only if a given file exists:
//
// IfExists("/foo/bar").Exec("/usr/bin/something")
func IfExists(path string) *Pipe {
_, err := os.Stat(path)
if err != nil {
return NewPipe().WithError(err)
}
return NewPipe()
}
// ListFiles creates a pipe containing the files or directories specified by
// path, one per line. path can be a glob expression, as for [filepath.Match].
// For example:
//
// ListFiles("/data/*").Stdout()
//
// ListFiles does not recurse into subdirectories; use [FindFiles] instead.
func ListFiles(path string) *Pipe {
if strings.ContainsAny(path, "[]^*?\\{}!") {
fileNames, err := filepath.Glob(path)
if err != nil {
return NewPipe().WithError(err)
}
return Slice(fileNames)
}
entries, err := os.ReadDir(path)
if err != nil {
// Check for the case where the path matches exactly one file
s, err := os.Stat(path)
if err != nil {
return NewPipe().WithError(err)
}
if !s.IsDir() {
return Echo(path)
}
return NewPipe().WithError(err)
}
matches := make([]string, len(entries))
for i, e := range entries {
matches[i] = filepath.Join(path, e.Name())
}
return Slice(matches)
}
// NewPipe creates a new pipe with an empty reader (use [Pipe.WithReader] to
// attach another reader to it).
func NewPipe() *Pipe {
return &Pipe{
Reader: ReadAutoCloser{},
mu: new(sync.Mutex),
stdout: os.Stdout,
httpClient: http.DefaultClient,
env: nil,
}
}
// Post creates a pipe that makes an HTTP POST request to url, with an empty
// body, and produces the response. See [Pipe.Do] for how the HTTP response
// status is interpreted.
func Post(url string) *Pipe {
return NewPipe().Post(url)
}
// Slice creates a pipe containing each element of s, one per line. If s is
// empty or nil, then the pipe is empty.
func Slice(s []string) *Pipe {
if len(s) == 0 {
return NewPipe()
}
return Echo(strings.Join(s, "\n") + "\n")
}
// Stdin creates a pipe that reads from [os.Stdin].
func Stdin() *Pipe {
return NewPipe().WithReader(os.Stdin)
}
// AppendFile appends the contents of the pipe to the file path, creating it if
// necessary, and returns the number of bytes successfully written, or an
// error.
func (p *Pipe) AppendFile(path string) (int64, error) {
return p.writeOrAppendFile(path, os.O_APPEND|os.O_CREATE|os.O_WRONLY)
}
// Basename reads paths from the pipe, one per line, and removes any leading
// directory components from each. So, for example, /usr/local/bin/foo would
// become just foo. This is the complementary operation to [Pipe.Dirname].
//
// If any line is empty, Basename will transform it to a single dot. Trailing
// slashes are removed. The behaviour of Basename is the same as
// [filepath.Base] (not by coincidence).
func (p *Pipe) Basename() *Pipe {
return p.FilterLine(filepath.Base)
}
// Bytes returns the contents of the pipe as a []byte, or an error.
func (p *Pipe) Bytes() ([]byte, error) {
if p.Error() != nil {
return nil, p.Error()
}
data, err := io.ReadAll(p)
if err != nil {
p.SetError(err)
}
return data, p.Error()
}
// Close closes the pipe's associated reader. This is a no-op if the reader is
// not an [io.Closer].
func (p *Pipe) Close() error {
return p.Reader.Close()
}
// Column produces column col of each line of input, where the first column is
// column 1, and columns are delimited by Unicode whitespace. Lines containing
// fewer than col columns will be skipped.
func (p *Pipe) Column(col int) *Pipe {
return p.FilterScan(func(line string, w io.Writer) {
columns := strings.Fields(line)
if col > 0 && col <= len(columns) {
fmt.Fprintln(w, columns[col-1])
}
})
}
// Concat reads paths from the pipe, one per line, and produces the contents of
// all the corresponding files in sequence. If there are any errors (for
// example, non-existent files), these will be ignored, execution will
// continue, and the pipe's error status will not be set.
//
// This makes it convenient to write programs that take a list of paths on the
// command line. For example:
//
// script.Args().Concat().Stdout()
//
// The list of paths could also come from a file:
//
// script.File("filelist.txt").Concat()
//
// Or from the output of a command:
//
// script.Exec("ls /var/app/config/").Concat().Stdout()
//
// Each input file will be closed once it has been fully read. If any of the
// files can't be opened or read, Concat will simply skip these and carry on,
// without setting the pipe's error status. This mimics the behaviour of Unix
// cat(1).
func (p *Pipe) Concat() *Pipe {
var readers []io.Reader
p.FilterScan(func(line string, w io.Writer) {
input, err := os.Open(line)
if err == nil {
readers = append(readers, NewReadAutoCloser(input))
}
}).Wait()
return p.WithReader(io.MultiReader(readers...))
}
// CountLines returns the number of lines of input, or an error.
func (p *Pipe) CountLines() (lines int, err error) {
p.FilterScan(func(line string, w io.Writer) {
lines++
}).Wait()
return lines, p.Error()
}
// DecodeBase64 produces the string represented by the base64 encoded input.
func (p *Pipe) DecodeBase64() *Pipe {
return p.Filter(func(r io.Reader, w io.Writer) error {
decoder := base64.NewDecoder(base64.StdEncoding, r)
_, err := io.Copy(w, decoder)
if err != nil {
return err
}
return nil
})
}
// Dirname reads paths from the pipe, one per line, and produces only the
// parent directories of each path. For example, /usr/local/bin/foo would
// become just /usr/local/bin. This is the complementary operation to
// [Pipe.Basename].
//
// If a line is empty, Dirname will transform it to a single dot. Trailing
// slashes are removed, unless Dirname returns the root folder. Otherwise, the
// behaviour of Dirname is the same as [filepath.Dir] (not by coincidence).
func (p *Pipe) Dirname() *Pipe {
return p.FilterLine(func(line string) string {
// filepath.Dir() does not handle trailing slashes correctly
if len(line) > 1 && strings.HasSuffix(line, "/") {
line = line[:len(line)-1]
}
dirname := filepath.Dir(line)
// filepath.Dir() does not preserve a leading './'
if strings.HasPrefix(line, "./") {
return "./" + dirname
}
return dirname
})
}
// Do performs the HTTP request req using the pipe's configured HTTP client, as
// set by [Pipe.WithHTTPClient], or [http.DefaultClient] otherwise. The
// response body is streamed concurrently to the pipe's output. If the response
// status is anything other than HTTP 200-299, the pipe's error status is set.
func (p *Pipe) Do(req *http.Request) *Pipe {
return p.Filter(func(r io.Reader, w io.Writer) error {
resp, err := p.httpClient.Do(req)
if err != nil {
return err
}
defer resp.Body.Close()
_, err = io.Copy(w, resp.Body)
if err != nil {
return err
}
// Any HTTP 2xx status code is considered okay
if resp.StatusCode/100 != 2 {
return fmt.Errorf("unexpected HTTP response status: %s", resp.Status)
}
return nil
})
}
// EachLine calls the function process on each line of input, passing it the
// line as a string, and a [*strings.Builder] to write its output to.
//
// Deprecated: use [Pipe.FilterLine] or [Pipe.FilterScan] instead, which run
// concurrently and don't do unnecessary reads on the input.
func (p *Pipe) EachLine(process func(string, *strings.Builder)) *Pipe {
return p.Filter(func(r io.Reader, w io.Writer) error {
scanner := newScanner(r)
output := new(strings.Builder)
for scanner.Scan() {
process(scanner.Text(), output)
}
fmt.Fprint(w, output.String())
return scanner.Err()
})
}
// Echo sets the pipe's reader to one that produces the string s, detaching any
// existing reader without draining or closing it.
func (p *Pipe) Echo(s string) *Pipe {
if p.Error() != nil {
return p
}
return p.WithReader(strings.NewReader(s))
}
// EncodeBase64 produces the base64 encoding of the input.
func (p *Pipe) EncodeBase64() *Pipe {
return p.Filter(func(r io.Reader, w io.Writer) error {
encoder := base64.NewEncoder(base64.StdEncoding, w)
defer encoder.Close()
_, err := io.Copy(encoder, r)
if err != nil {
return err
}
return nil
})
}
func (p *Pipe) environment() []string {
p.mu.Lock()
defer p.mu.Unlock()
return p.env
}
// Error returns any error present on the pipe, or nil otherwise.
// Error is not a sink and does not wait until the pipe reaches
// completion. To wait for completion before returning the error,
// see [Pipe.Wait].
func (p *Pipe) Error() error {
if p.mu == nil { // uninitialised pipe
return nil
}
p.mu.Lock()
defer p.mu.Unlock()
return p.err
}
// Exec runs cmdLine as an external command, sending it the contents of the
// pipe as input, and produces the command's standard output (see below for
// error output). The effect of this is to filter the contents of the pipe
// through the external command.
//
// # Environment
//
// The command inherits the current process's environment, optionally modified
// by [Pipe.WithEnv].
//
// # Error handling
//
// If the command had a non-zero exit status, the pipe's error status will also
// be set to the string “exit status X”, where X is the integer exit status.
// Even in the event of a non-zero exit status, the command's output will still
// be available in the pipe. This is often helpful for debugging. However,
// because [Pipe.String] is a no-op if the pipe's error status is set, if you
// want output you will need to reset the error status before calling
// [Pipe.String].
//
// If the command writes to its standard error stream, this will also go to the
// pipe, along with its standard output. However, the standard error text can
// instead be redirected to a supplied writer, using [Pipe.WithStderr].
func (p *Pipe) Exec(cmdLine string) *Pipe {
return p.Filter(func(r io.Reader, w io.Writer) error {
args, err := shell.Fields(cmdLine, nil)
if err != nil {
return err
}
cmd := exec.Command(args[0], args[1:]...)
cmd.Stdin = r
cmd.Stdout = w
cmd.Stderr = w
pipeStderr := p.stdErr()
if pipeStderr != nil {
cmd.Stderr = pipeStderr
}
pipeEnv := p.environment()
if pipeEnv != nil {
cmd.Env = pipeEnv
}
err = cmd.Start()
if err != nil {
fmt.Fprintln(cmd.Stderr, err)
return err
}
return cmd.Wait()
})
}
// ExecForEach renders cmdLine as a Go template for each line of input, running
// the resulting command, and produces the combined output of all these
// commands in sequence. See [Pipe.Exec] for details on error handling and
// environment variables.
//
// This is mostly useful for substituting data into commands using Go template
// syntax. For example:
//
// ListFiles("*").ExecForEach("touch {{.}}").Wait()
func (p *Pipe) ExecForEach(cmdLine string) *Pipe {
tpl, err := template.New("").Parse(cmdLine)
if err != nil {
return p.WithError(err)
}
return p.Filter(func(r io.Reader, w io.Writer) error {
scanner := newScanner(r)
for scanner.Scan() {
cmdLine := new(strings.Builder)
err := tpl.Execute(cmdLine, scanner.Text())
if err != nil {
return err
}
args, err := shell.Fields(cmdLine.String(), nil)
if err != nil {
return err
}
cmd := exec.Command(args[0], args[1:]...)
cmd.Stdout = w
cmd.Stderr = w
pipeStderr := p.stdErr()
if pipeStderr != nil {
cmd.Stderr = pipeStderr
}
if p.env != nil {
cmd.Env = p.env
}
err = cmd.Start()
if err != nil {
fmt.Fprintln(cmd.Stderr, err)
continue
}
err = cmd.Wait()
if err != nil {
fmt.Fprintln(cmd.Stderr, err)
continue
}
}
return scanner.Err()
})
}
var exitStatusPattern = regexp.MustCompile(`exit status (\d+)$`)
// ExitStatus returns the integer exit status of a previous command (for
// example run by [Pipe.Exec]). This will be zero unless the pipe's error
// status is set and the error matches the pattern “exit status %d”.
func (p *Pipe) ExitStatus() int {
if p.Error() == nil {
return 0
}
match := exitStatusPattern.FindStringSubmatch(p.Error().Error())
if len(match) < 2 {
return 0
}
status, err := strconv.Atoi(match[1])
if err != nil {
// This seems unlikely, but...
return 0
}
return status
}
// Filter sends the contents of the pipe to the function filter and produces
// the result. filter takes an [io.Reader] to read its input from and an
// [io.Writer] to write its output to, and returns an error, which will be set
// on the pipe.
//
// filter runs concurrently, so its goroutine will not exit until the pipe has
// been fully read. Use [Pipe.Wait] to wait for all concurrent filters to
// complete.
func (p *Pipe) Filter(filter func(io.Reader, io.Writer) error) *Pipe {
if p.Error() != nil {
return p
}
pr, pw := io.Pipe()
origReader := p.Reader
p = p.WithReader(pr)
go func() {
defer pw.Close()
err := filter(origReader, pw)
if err != nil {
p.SetError(err)
}
}()
return p
}
// FilterLine sends the contents of the pipe to the function filter, a line at
// a time, and produces the result. filter takes each line as a string and
// returns a string as its output. See [Pipe.Filter] for concurrency handling.
func (p *Pipe) FilterLine(filter func(string) string) *Pipe {
return p.FilterScan(func(line string, w io.Writer) {
fmt.Fprintln(w, filter(line))
})
}
// FilterScan sends the contents of the pipe to the function filter, a line at
// a time, and produces the result. filter takes each line as a string and an
// [io.Writer] to write its output to. See [Pipe.Filter] for concurrency
// handling.
func (p *Pipe) FilterScan(filter func(string, io.Writer)) *Pipe {
return p.Filter(func(r io.Reader, w io.Writer) error {
scanner := newScanner(r)
for scanner.Scan() {
filter(scanner.Text(), w)
}
return scanner.Err()
})
}
// First produces only the first n lines of the pipe's contents, or all the
// lines if there are less than n. If n is zero or negative, there is no output
// at all. When n lines have been produced, First stops reading its input and
// sends EOF to its output.
func (p *Pipe) First(n int) *Pipe {
if p.Error() != nil {
return p
}
if n <= 0 {
return NewPipe()
}
return p.Filter(func(r io.Reader, w io.Writer) error {
scanner := newScanner(r)
for i := 0; i < n && scanner.Scan(); i++ {
_, err := fmt.Fprintln(w, scanner.Text())
if err != nil {
return err
}
}
return scanner.Err()
})
}
// Freq produces only the unique lines from the pipe's contents, each prefixed
// with a frequency count, in descending numerical order (most frequent lines
// first). Lines with equal frequency will be sorted alphabetically.
//
// For example, we could take a common shell pipeline like this:
//
// sort input.txt |uniq -c |sort -rn
//
// and replace it with:
//
// File("input.txt").Freq().Stdout()
//
// Or to get only the ten most common lines:
//
// File("input.txt").Freq().First(10).Stdout()
//
// Like Unix uniq(1), Freq right-justifies its count values in a column for
// readability, padding with spaces if necessary.
func (p *Pipe) Freq() *Pipe {
freq := map[string]int{}
type frequency struct {
line string
count int
}
return p.Filter(func(r io.Reader, w io.Writer) error {
scanner := newScanner(r)
for scanner.Scan() {
freq[scanner.Text()]++
}
freqs := make([]frequency, 0, len(freq))
max := 0
for line, count := range freq {
freqs = append(freqs, frequency{line, count})
if count > max {
max = count
}
}
sort.Slice(freqs, func(i, j int) bool {
x, y := freqs[i].count, freqs[j].count
if x == y {
return freqs[i].line < freqs[j].line
}
return x > y
})
fieldWidth := len(strconv.Itoa(max))
for _, item := range freqs {
fmt.Fprintf(w, "%*d %s\n", fieldWidth, item.count, item.line)
}
return nil
})
}
// Get makes an HTTP GET request to url, sending the contents of the pipe as
// the request body, and produces the server's response. See [Pipe.Do] for how
// the HTTP response status is interpreted.
func (p *Pipe) Get(url string) *Pipe {
req, err := http.NewRequest(http.MethodGet, url, p.Reader)
if err != nil {
return p.WithError(err)
}
return p.Do(req)
}
// Hash returns the hex-encoded hash of the entire contents of the
// pipe based on the provided hasher, or an error.
// To perform hashing on files, see [Pipe.HashSums].
func (p *Pipe) Hash(hasher hash.Hash) (string, error) {
if p.Error() != nil {
return "", p.Error()
}
_, err := io.Copy(hasher, p)
if err != nil {
p.SetError(err)
return "", err
}
return hex.EncodeToString(hasher.Sum(nil)), nil
}
// HashSums reads paths from the pipe, one per line, and produces the
// hex-encoded hash of each corresponding file based on the provided hasher,
// one per line. Any files that cannot be opened or read will be ignored.
// To perform hashing on the contents of the pipe, see [Pipe.Hash].
func (p *Pipe) HashSums(hasher hash.Hash) *Pipe {
return p.FilterScan(func(line string, w io.Writer) {
f, err := os.Open(line)
if err != nil {
return // skip unopenable files
}
defer f.Close()
_, err = io.Copy(hasher, f)
if err != nil {
return // skip unreadable files
}
fmt.Fprintln(w, hex.EncodeToString(hasher.Sum(nil)))
})
}
// Join joins all the lines in the pipe's contents into a single
// space-separated string, which will always end with a newline.
func (p *Pipe) Join() *Pipe {
return p.Filter(func(r io.Reader, w io.Writer) error {
scanner := newScanner(r)
first := true
for scanner.Scan() {
if !first {
fmt.Fprint(w, " ")
}
line := scanner.Text()
fmt.Fprint(w, line)
first = false
}
fmt.Fprintln(w)
return scanner.Err()
})
}
// JQ executes query on the pipe's contents (presumed to be JSON), producing
// the result. An invalid query will set the appropriate error on the pipe.
//
// The exact dialect of JQ supported is that provided by
// [github.com/itchyny/gojq], whose documentation explains the differences
// between it and standard JQ.
func (p *Pipe) JQ(query string) *Pipe {
return p.Filter(func(r io.Reader, w io.Writer) error {
q, err := gojq.Parse(query)
if err != nil {
return err
}
var input interface{}
err = json.NewDecoder(r).Decode(&input)
if err != nil {
return err
}
iter := q.Run(input)
for {
v, ok := iter.Next()
if !ok {
return nil
}
if err, ok := v.(error); ok {
return err
}
result, err := gojq.Marshal(v)
if err != nil {
return err
}
fmt.Fprintln(w, string(result))
}
})
}
// Last produces only the last n lines of the pipe's contents, or all the lines
// if there are less than n. If n is zero or negative, there is no output at
// all.
func (p *Pipe) Last(n int) *Pipe {
if p.Error() != nil {
return p
}
if n <= 0 {
return NewPipe()
}
return p.Filter(func(r io.Reader, w io.Writer) error {
scanner := newScanner(r)
input := ring.New(n)
for scanner.Scan() {
input.Value = scanner.Text()
input = input.Next()
}
input.Do(func(p interface{}) {
if p != nil {
fmt.Fprintln(w, p)
}
})
return scanner.Err()
})
}
// Match produces only the input lines that contain the string s.
func (p *Pipe) Match(s string) *Pipe {
return p.FilterScan(func(line string, w io.Writer) {
if strings.Contains(line, s) {
fmt.Fprintln(w, line)
}
})
}
// MatchRegexp produces only the input lines that match the compiled regexp re.
func (p *Pipe) MatchRegexp(re *regexp.Regexp) *Pipe {
return p.FilterScan(func(line string, w io.Writer) {
if re.MatchString(line) {
fmt.Fprintln(w, line)
}
})
}
// Post makes an HTTP POST request to url, using the contents of the pipe as
// the request body, and produces the server's response. See [Pipe.Do] for how
// the HTTP response status is interpreted.
func (p *Pipe) Post(url string) *Pipe {
req, err := http.NewRequest(http.MethodPost, url, p.Reader)
if err != nil {
return p.WithError(err)
}
return p.Do(req)
}
// Reject produces only lines that do not contain the string s.
func (p *Pipe) Reject(s string) *Pipe {
return p.FilterScan(func(line string, w io.Writer) {
if !strings.Contains(line, s) {
fmt.Fprintln(w, line)
}
})
}
// RejectRegexp produces only lines that don't match the compiled regexp re.
func (p *Pipe) RejectRegexp(re *regexp.Regexp) *Pipe {
return p.FilterScan(func(line string, w io.Writer) {
if !re.MatchString(line) {
fmt.Fprintln(w, line)
}
})
}
// Replace replaces all occurrences of the string search with the string
// replace.
func (p *Pipe) Replace(search, replace string) *Pipe {
return p.FilterLine(func(line string) string {
return strings.ReplaceAll(line, search, replace)
})
}
// ReplaceRegexp replaces all matches of the compiled regexp re with the string
// replace. $x variables in the replace string are interpreted as by
// [regexp#Regexp.Expand]; for example, $1 represents the text of the first submatch.
func (p *Pipe) ReplaceRegexp(re *regexp.Regexp, replace string) *Pipe {
return p.FilterLine(func(line string) string {
return re.ReplaceAllString(line, replace)
})
}
// Read reads up to len(b) bytes from the pipe into b. It returns the number of
// bytes read and any error encountered. At end of file, or on a nil pipe, Read
// returns 0, [io.EOF].
func (p *Pipe) Read(b []byte) (int, error) {
if p.Error() != nil {
return 0, p.Error()
}
return p.Reader.Read(b)
}
// SetError sets the error err on the pipe.
func (p *Pipe) SetError(err error) {
if p.mu == nil { // uninitialised pipe
return
}
p.mu.Lock()
defer p.mu.Unlock()
p.err = err
}
// SHA256Sum returns the hex-encoded SHA-256 hash of the entire contents of the
// pipe, or an error.
// Deprecated: SHA256Sum has been deprecated by [Pipe.Hash]. To get the SHA-256
// hash for the contents of the pipe, call `Hash(sha256.new())`
func (p *Pipe) SHA256Sum() (string, error) {
return p.Hash(sha256.New())
}
// SHA256Sums reads paths from the pipe, one per line, and produces the
// hex-encoded SHA-256 hash of each corresponding file, one per line. Any files
// that cannot be opened or read will be ignored.
// Deprecated: SHA256Sums has been deprecated by [Pipe.HashSums]. To get the SHA-256
// hash for each file path in the pipe, call `HashSums(sha256.new())`
func (p *Pipe) SHA256Sums() *Pipe {
return p.HashSums(sha256.New())
}
// Slice returns the pipe's contents as a slice of strings, one element per
// line, or an error.
//
// An empty pipe will produce an empty slice. A pipe containing a single empty
// line (that is, a single \n character) will produce a slice containing the
// empty string as its single element.
func (p *Pipe) Slice() ([]string, error) {
result := []string{}
p.FilterScan(func(line string, w io.Writer) {
result = append(result, line)
}).Wait()
return result, p.Error()
}
// stdErr returns the pipe's configured standard error writer for commands run
// via [Pipe.Exec] and [Pipe.ExecForEach]. The default is nil, which means that
// error output will go to the pipe.
func (p *Pipe) stdErr() io.Writer {
if p.mu == nil { // uninitialised pipe
return nil
}
p.mu.Lock()
defer p.mu.Unlock()
return p.stderr
}
// Stdout copies the pipe's contents to its configured standard output (using
// [Pipe.WithStdout]), or to [os.Stdout] otherwise, and returns the number of
// bytes successfully written, together with any error.
func (p *Pipe) Stdout() (int, error) {
if p.Error() != nil {
return 0, p.Error()
}
n64, err := io.Copy(p.stdout, p)
if err != nil {
return 0, err
}
n := int(n64)
if int64(n) != n64 {
return 0, fmt.Errorf("length %d overflows int", n64)
}
return n, p.Error()
}
// String returns the pipe's contents as a string, together with any error.
func (p *Pipe) String() (string, error) {
data, err := p.Bytes()
if err != nil {
p.SetError(err)
}
return string(data), p.Error()
}
// Tee copies the pipe's contents to each of the supplied writers, like Unix
// tee(1). If no writers are supplied, the default is the pipe's standard
// output.
func (p *Pipe) Tee(writers ...io.Writer) *Pipe {
teeWriter := p.stdout
if len(writers) > 0 {
teeWriter = io.MultiWriter(writers...)
}
return p.WithReader(io.TeeReader(p.Reader, teeWriter))
}
// Wait reads the pipe to completion and returns any error present on
// the pipe, or nil otherwise. This is mostly useful for waiting until
// concurrent filters have completed (see [Pipe.Filter]).
func (p *Pipe) Wait() error {
_, err := io.Copy(io.Discard, p)
if err != nil {
p.SetError(err)
}
return p.Error()
}
// WithEnv sets the environment for subsequent [Pipe.Exec] and [Pipe.ExecForEach]
// commands to the string slice env, using the same format as [os/exec.Cmd.Env].
// An empty slice unsets all existing environment variables.
func (p *Pipe) WithEnv(env []string) *Pipe {
p.mu.Lock()
defer p.mu.Unlock()
p.env = env
return p
}
// WithError sets the error err on the pipe.
func (p *Pipe) WithError(err error) *Pipe {
p.SetError(err)
return p
}
// WithHTTPClient sets the HTTP client c for use with subsequent requests via
// [Pipe.Do], [Pipe.Get], or [Pipe.Post]. For example, to make a request using
// a client with a timeout:
//
// NewPipe().WithHTTPClient(&http.Client{
// Timeout: 10 * time.Second,
// }).Get("https://example.com").Stdout()
func (p *Pipe) WithHTTPClient(c *http.Client) *Pipe {
p.httpClient = c
return p
}
// WithReader sets the pipe's input reader to r. Once r has been completely
// read, it will be closed if necessary.
func (p *Pipe) WithReader(r io.Reader) *Pipe {
p.Reader = NewReadAutoCloser(r)
return p
}
// WithStderr sets the standard error output for [Pipe.Exec] or
// [Pipe.ExecForEach] commands to w, instead of the pipe.
func (p *Pipe) WithStderr(w io.Writer) *Pipe {
p.mu.Lock()
defer p.mu.Unlock()
p.stderr = w
return p
}
// WithStdout sets the pipe's standard output to the writer w, instead of the
// default [os.Stdout].
func (p *Pipe) WithStdout(w io.Writer) *Pipe {
p.stdout = w
return p