elvish/pkg/eval/port.go
2021-01-27 01:30:25 +00:00

233 lines
5.6 KiB
Go

package eval
import (
"bufio"
"fmt"
"io"
"os"
"sync"
"src.elv.sh/pkg/eval/vals"
"src.elv.sh/pkg/strutil"
)
// Port conveys data stream. It always consists of a byte band and a channel band.
type Port struct {
File *os.File
Chan chan interface{}
closeFile bool
closeChan bool
}
// Returns a copy of the Port with the Close* flags unset.
func (p *Port) fork() *Port {
return &Port{p.File, p.Chan, false, false}
}
// Closes a Port.
func (p *Port) close() {
if p == nil {
return
}
if p.closeFile {
p.File.Close()
}
if p.closeChan {
close(p.Chan)
}
}
var (
// ClosedChan is a closed channel, suitable as a placeholder input channel.
ClosedChan = getClosedChan()
// BlackholeChan is a channel that absorbs all values written to it,
// suitable as a placeholder output channel.
BlackholeChan = getBlackholeChan()
// DevNull is /dev/null, suitable as a placeholder file for either input or
// output.
DevNull = getDevNull()
// DummyInputPort is a port made up from DevNull and ClosedChan, suitable as
// a placeholder input port.
DummyInputPort = &Port{File: DevNull, Chan: ClosedChan}
// DummyOutputPort is a port made up from DevNull and BlackholeChan,
// suitable as a placeholder output port.
DummyOutputPort = &Port{File: DevNull, Chan: BlackholeChan}
)
func getClosedChan() chan interface{} {
ch := make(chan interface{})
close(ch)
return ch
}
func getBlackholeChan() chan interface{} {
ch := make(chan interface{})
go func() {
for range ch {
}
}()
return ch
}
func getDevNull() *os.File {
f, err := os.Open(os.DevNull)
if err != nil {
fmt.Fprintf(os.Stderr,
"cannot open %s, shell might not function normally\n", os.DevNull)
}
return f
}
// PipePort returns an output *Port whose value and byte components are both
// piped. The supplied functions are called on a separate goroutine with the
// read ends of the value and byte components of the port. It also returns a
// function to clean up the port and wait for the callbacks to finish.
func PipePort(vCb func(<-chan interface{}), bCb func(*os.File)) (*Port, func(), error) {
r, w, err := os.Pipe()
if err != nil {
return nil, nil, err
}
ch := make(chan interface{}, outputCaptureBufferSize)
var wg sync.WaitGroup
wg.Add(2)
go func() {
defer wg.Done()
vCb(ch)
}()
go func() {
defer wg.Done()
defer r.Close()
bCb(r)
}()
port := &Port{Chan: ch, closeChan: true, File: w, closeFile: true}
done := func() {
port.close()
wg.Wait()
}
return port, done, nil
}
// CapturePort returns an output *Port whose value and byte components are
// both connected to an internal pipe that saves the output. It also returns a
// function to call to obtain the captured output.
func CapturePort() (*Port, func() []interface{}, error) {
vs := []interface{}{}
var m sync.Mutex
port, done, err := PipePort(
func(ch <-chan interface{}) {
for v := range ch {
m.Lock()
vs = append(vs, v)
m.Unlock()
}
},
func(r *os.File) {
buffered := bufio.NewReader(r)
for {
line, err := buffered.ReadString('\n')
if line != "" {
v := strutil.ChopLineEnding(line)
m.Lock()
vs = append(vs, v)
m.Unlock()
}
if err != nil {
if err != io.EOF {
logger.Println("error on reading:", err)
}
break
}
}
})
if err != nil {
return nil, nil, err
}
return port, func() []interface{} {
done()
return vs
}, nil
}
// StringCapturePort is like CapturePort, but processes value outputs by
// stringifying them and prepending an output marker.
func StringCapturePort() (*Port, func() []string, error) {
var lines []string
var mu sync.Mutex
addLine := func(line string) {
mu.Lock()
defer mu.Unlock()
lines = append(lines, line)
}
port, done, err := PipePort(
func(ch <-chan interface{}) {
for v := range ch {
addLine("▶ " + vals.ToString(v))
}
},
func(r *os.File) {
bufr := bufio.NewReader(r)
for {
line, err := bufr.ReadString('\n')
if err != nil {
if err != io.EOF {
addLine("i/o error: " + err.Error())
}
break
}
addLine(strutil.ChopLineEnding(line))
}
})
if err != nil {
return nil, nil, err
}
return port, func() []string {
done()
return lines
}, nil
}
// Buffer size for the channel to use in FilePort. The value has been chosen
// arbitrarily.
const filePortChanSize = 32
// FilePort returns an output *Port where the byte component is the file itself,
// and the value component is converted to an internal channel that writes
// each value to the file, prepending with a prefix. It also returns a cleanup
// function, which should be called when the *Port is no longer needed.
func FilePort(f *os.File, valuePrefix string) (*Port, func()) {
ch := make(chan interface{}, filePortChanSize)
relayDone := make(chan struct{})
go func() {
for v := range ch {
f.WriteString(valuePrefix)
f.WriteString(vals.Repr(v, vals.NoPretty))
f.WriteString("\n")
}
close(relayDone)
}()
return &Port{File: f, Chan: ch}, func() {
close(ch)
<-relayDone
}
}
// PortsFromStdFiles is a shorthand for calling PortsFromFiles with os.Stdin,
// os.Stdout and os.Stderr.
func PortsFromStdFiles(prefix string) ([]*Port, func()) {
return PortsFromFiles([3]*os.File{os.Stdin, os.Stdout, os.Stderr}, prefix)
}
// PortsFromFiles builds 3 ports from 3 files. It also returns a function that
// should be called when the ports are no longer needed.
func PortsFromFiles(files [3]*os.File, prefix string) ([]*Port, func()) {
port1, cleanup1 := FilePort(files[1], prefix)
port2, cleanup2 := FilePort(files[2], prefix)
return []*Port{{File: files[0], Chan: ClosedChan}, port1, port2}, func() {
cleanup1()
cleanup2()
}
}