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