VictoriaMetrics/vendor/github.com/ergochat/readline/terminal.go

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package readline
import (
"bufio"
"bytes"
"errors"
"fmt"
"io"
"strconv"
"sync"
"sync/atomic"
"time"
"github.com/ergochat/readline/internal/ansi"
"github.com/ergochat/readline/internal/platform"
)
const (
// see waitForDSR
dsrTimeout = 250 * time.Millisecond
maxAnsiLen = 32
// how many non-CPR reads to buffer while waiting for a CPR response
maxCPRBufferLen = 128 * 1024
)
var (
deadlineExceeded = errors.New("deadline exceeded")
concurrentReads = errors.New("concurrent read operations detected")
invalidCPR = errors.New("invalid CPR response")
)
/*
terminal manages terminal input. The design constraints here are somewhat complex:
1. Calls to (*Instance).Readline() must always be preemptible by (*Instance).Close.
This could be handled at the Operation layer instead; however, it's cleaner
to provide an API in terminal itself that can interrupt attempts to read.
2. In between calls to Readline(), or *after* a call to (*Instance).Close(),
stdin must be available for code outside of this library to read from. The
problem is that reads from stdin in Go are not preemptible (see, for example,
https://github.com/golang/go/issues/24842 ). In the worst case, an
interrupted read will leave (*terminal).ioloop() running, and it will
consume one more user keystroke before it exits. However, it is a design goal
to read as little as possible at a time.
3. We have to handle the DSR ("device status report") query and the
CPR ("cursor position report") response:
https://vt100.net/docs/vt510-rm/DSR-CPR.html
This involves writing an ANSI escape sequence to stdout, then waiting
for the terminal to asynchronously write an ANSI escape sequence to stdin.
We have to pick this value out of the stream and process it without
disrupting the handling of actual user input. Moreover, concurrent Close()
while a CPR query is in flight should ensure (if possible) that the
response is actually read; otherwise the response may be printed to the
screen, disrupting the user experience.
Accordingly, the concurrency design is as follows:
1. ioloop() runs asynchronously. It operates in lockstep with the read methods:
each synchronous receive from kickChan is matched with a synchronous send to
outChan. It does blocking reads from stdin, reading as little as possible at
a time, and passing the results back over outChan.
2. The read methods ("internal public API") GetRune() and GetCursorPosition()
are not concurrency-safe and must be called in serial. They are backed by
readFromStdin, which wakes ioloop() if necessary and waits for a response.
If GetCursorPosition() reads non-CPR data, it will buffer it for GetRune()
to read later.
3. Close() can be called asynchronously. It interrupts ioloop() (unless ioloop()
is actually reading from stdin, in which case it interrupts it after the next
keystroke), and also interrupts any in-progress GetRune() call. If
GetCursorPosition() is in progress, it tries to wait until the CPR response
has been received. It is idempotent and can be called multiple times.
*/
type terminal struct {
cfg atomic.Pointer[Config]
dimensions atomic.Pointer[termDimensions]
closeOnce sync.Once
closeErr error
outChan chan readResult
kickChan chan struct{}
stopChan chan struct{}
buffer []rune // actual input that we saw while waiting for the CPR
inFlight bool // tracks whether we initiated a read and then gave up waiting
sleeping int32
// asynchronously receive DSR messages from the terminal,
// ensuring at most one query is in flight at a time
dsrLock sync.Mutex
dsrDone chan struct{} // nil if there is no DSR query in flight
}
// termDimensions stores the terminal width and height (-1 means unknown)
type termDimensions struct {
width int
height int
}
type cursorPosition struct {
row int
col int
}
// readResult represents the result of a single "read operation" from the
// perspective of terminal. it may be a pure no-op. the consumer needs to
// read again if it didn't get what it wanted
type readResult struct {
r rune
ok bool // is `r` valid user input? if not, we may need to read again
// other data that can be conveyed in a single read operation;
// currently only the CPR:
pos *cursorPosition
}
func newTerminal(cfg *Config) (*terminal, error) {
if cfg.isInteractive {
if ansiErr := ansi.EnableANSI(); ansiErr != nil {
return nil, fmt.Errorf("Could not enable ANSI escapes: %w", ansiErr)
}
}
t := &terminal{
kickChan: make(chan struct{}),
outChan: make(chan readResult),
stopChan: make(chan struct{}),
}
t.SetConfig(cfg)
// Get and cache the current terminal size.
t.OnSizeChange()
go t.ioloop()
return t, nil
}
// SleepToResume will sleep myself, and return only if I'm resumed.
func (t *terminal) SleepToResume() {
if !atomic.CompareAndSwapInt32(&t.sleeping, 0, 1) {
return
}
defer atomic.StoreInt32(&t.sleeping, 0)
t.ExitRawMode()
platform.SuspendProcess()
t.EnterRawMode()
}
func (t *terminal) EnterRawMode() (err error) {
return t.GetConfig().FuncMakeRaw()
}
func (t *terminal) ExitRawMode() (err error) {
return t.GetConfig().FuncExitRaw()
}
func (t *terminal) Write(b []byte) (int, error) {
return t.GetConfig().Stdout.Write(b)
}
// getOffset sends a DSR query to get the current offset, then blocks
// until the query returns.
func (t *terminal) GetCursorPosition(deadline chan struct{}) (cursorPosition, error) {
// ensure there is no in-flight query, set up a waiter
ok := func() (ok bool) {
t.dsrLock.Lock()
defer t.dsrLock.Unlock()
if t.dsrDone == nil {
t.dsrDone = make(chan struct{})
ok = true
}
return
}()
if !ok {
return cursorPosition{-1, -1}, concurrentReads
}
defer func() {
t.dsrLock.Lock()
defer t.dsrLock.Unlock()
close(t.dsrDone)
t.dsrDone = nil
}()
// send the DSR Cursor Position Report request to terminal stdout:
// https://vt100.net/docs/vt510-rm/DSR-CPR.html
_, err := t.Write([]byte("\x1b[6n"))
if err != nil {
return cursorPosition{-1, -1}, err
}
for {
result, err := t.readFromStdin(deadline)
if err != nil {
return cursorPosition{-1, -1}, err
}
if result.ok {
// non-CPR input, save it to be read later:
t.buffer = append(t.buffer, result.r)
if len(t.buffer) > maxCPRBufferLen {
panic("did not receive DSR CPR response")
}
}
if result.pos != nil {
return *result.pos, nil
}
}
}
// waitForDSR waits for any in-flight DSR query to complete. this prevents
// garbage from being written to the terminal when Close() interrupts an
// in-flight query.
func (t *terminal) waitForDSR() {
t.dsrLock.Lock()
dsrDone := t.dsrDone
t.dsrLock.Unlock()
if dsrDone != nil {
// tradeoffs: if the timeout is too high, we risk slowing down Close();
// if it's too low, we risk writing the CPR to the terminal, which is bad UX,
// but neither of these outcomes is catastrophic
timer := time.NewTimer(dsrTimeout)
select {
case <-dsrDone:
case <-timer.C:
}
timer.Stop()
}
}
func (t *terminal) GetRune(deadline chan struct{}) (rune, error) {
if len(t.buffer) > 0 {
result := t.buffer[0]
t.buffer = t.buffer[1:]
return result, nil
}
return t.getRuneFromStdin(deadline)
}
func (t *terminal) getRuneFromStdin(deadline chan struct{}) (rune, error) {
for {
result, err := t.readFromStdin(deadline)
if err != nil {
return 0, err
} else if result.ok {
return result.r, nil
} // else: CPR or something else we didn't understand, read again
}
}
func (t *terminal) readFromStdin(deadline chan struct{}) (result readResult, err error) {
// we may have sent a kick previously and given up on the response;
// if so, don't kick again (we will try again to read the pending response)
if !t.inFlight {
select {
case t.kickChan <- struct{}{}:
t.inFlight = true
case <-t.stopChan:
return result, io.EOF
case <-deadline:
return result, deadlineExceeded
}
}
select {
case result = <-t.outChan:
t.inFlight = false
return result, nil
case <-t.stopChan:
return result, io.EOF
case <-deadline:
return result, deadlineExceeded
}
}
func (t *terminal) ioloop() {
// ensure close if we get an error from stdio
defer t.Close()
buf := bufio.NewReader(t.GetConfig().Stdin)
var ansiBuf bytes.Buffer
for {
select {
case <-t.kickChan:
case <-t.stopChan:
return
}
r, _, err := buf.ReadRune()
if err != nil {
return
}
var result readResult
if r == '\x1b' {
// we're starting an ANSI escape sequence:
// keep reading until we reach the end of the sequence
result, err = t.consumeANSIEscape(buf, &ansiBuf)
if err != nil {
return
}
} else {
result = readResult{r: r, ok: true}
}
select {
case t.outChan <- result:
case <-t.stopChan:
return
}
}
}
func (t *terminal) consumeANSIEscape(buf *bufio.Reader, ansiBuf *bytes.Buffer) (result readResult, err error) {
ansiBuf.Reset()
initial, _, err := buf.ReadRune()
if err != nil {
return
}
// we already read one \x1b. this can indicate either the start of an ANSI
// escape sequence, or a keychord with Alt (e.g. Alt+f produces `\x1bf` in
// a typical xterm).
switch initial {
case 'f':
// Alt-f in xterm, or Option+RightArrow in iTerm2 with "Natural text editing"
return readResult{r: MetaForward, ok: true}, nil // Alt-f
case 'b':
// Alt-b in xterm, or Option+LeftArrow in iTerm2 with "Natural text editing"
return readResult{r: MetaBackward, ok: true}, nil // Alt-b
case '[', 'O':
// this is a real ANSI escape sequence, read the rest of the sequence below:
case '\x1b':
// Alt plus a real ANSI escape sequence. Handle this specially since
// right now the only cases we want to handle are the arrow keys:
return consumeAltSequence(buf)
default:
return // invalid, ignore
}
// data consists of ; and 0-9 , anything else terminates the sequence
var type_ rune
for {
r, _, err := buf.ReadRune()
if err != nil {
return result, err
}
if r == ';' || ('0' <= r && r <= '9') {
ansiBuf.WriteRune(r)
} else {
type_ = r
break
}
}
var r rune
switch type_ {
case 'R':
if initial == '[' {
// DSR CPR response; if we can't parse it, just ignore it
// (do not return an error here because that would stop ioloop())
if cpos, err := parseCPRResponse(ansiBuf.Bytes()); err == nil {
return readResult{r: 0, ok: false, pos: &cpos}, nil
}
}
case 'D':
if altModifierEnabled(ansiBuf.Bytes()) {
r = MetaBackward
} else {
r = CharBackward
}
case 'C':
if altModifierEnabled(ansiBuf.Bytes()) {
r = MetaForward
} else {
r = CharForward
}
case 'A':
r = CharPrev
case 'B':
r = CharNext
case 'H':
r = CharLineStart
case 'F':
r = CharLineEnd
case '~':
if initial == '[' {
switch string(ansiBuf.Bytes()) {
case "3":
r = MetaDeleteKey // this is the key typically labeled "Delete"
case "1", "7":
r = CharLineStart // "Home" key
case "4", "8":
r = CharLineEnd // "End" key
}
}
case 'Z':
if initial == '[' {
r = MetaShiftTab
}
}
if r != 0 {
return readResult{r: r, ok: true}, nil
}
return // default: no interpretable rune value
}
func consumeAltSequence(buf *bufio.Reader) (result readResult, err error) {
initial, _, err := buf.ReadRune()
if err != nil {
return
}
if initial != '[' {
return
}
second, _, err := buf.ReadRune()
if err != nil {
return
}
switch second {
case 'D':
return readResult{r: MetaBackward, ok: true}, nil
case 'C':
return readResult{r: MetaForward, ok: true}, nil
default:
return
}
}
func altModifierEnabled(payload []byte) bool {
// https://www.xfree86.org/current/ctlseqs.html ; modifier keycodes
// go after the semicolon, e.g. Alt-LeftArrow is `\x1b[1;3D` in VTE
// terminals, where 3 indicates Alt
if semicolonIdx := bytes.IndexByte(payload, ';'); semicolonIdx != -1 {
if string(payload[semicolonIdx+1:]) == "3" {
return true
}
}
return false
}
func parseCPRResponse(payload []byte) (cursorPosition, error) {
if semicolonIdx := bytes.IndexByte(payload, ';'); semicolonIdx != -1 {
if row, err := strconv.Atoi(string(payload[:semicolonIdx])); err == nil {
if col, err := strconv.Atoi(string(payload[semicolonIdx+1:])); err == nil {
return cursorPosition{row: row, col: col}, nil
}
}
}
return cursorPosition{-1, -1}, invalidCPR
}
func (t *terminal) Bell() {
t.Write([]byte{CharBell})
}
func (t *terminal) Close() error {
t.closeOnce.Do(func() {
t.waitForDSR()
close(t.stopChan)
// don't close outChan; outChan results should always be valid.
// instead we always select on both outChan and stopChan
t.closeErr = t.ExitRawMode()
})
return t.closeErr
}
func (t *terminal) SetConfig(c *Config) error {
t.cfg.Store(c)
return nil
}
func (t *terminal) GetConfig() *Config {
return t.cfg.Load()
}
// OnSizeChange gets the current terminal size and caches it
func (t *terminal) OnSizeChange() {
cfg := t.GetConfig()
width, height := cfg.FuncGetSize()
t.dimensions.Store(&termDimensions{
width: width,
height: height,
})
}
// GetWidthHeight returns the cached width, height values from the terminal
func (t *terminal) GetWidthHeight() (width, height int) {
dimensions := t.dimensions.Load()
return dimensions.width, dimensions.height
}