bubbletea/standard_renderer.go

658 lines
17 KiB
Go

package tea
import (
"bytes"
"fmt"
"io"
"strings"
"sync"
"time"
"github.com/muesli/ansi/compressor"
"github.com/muesli/reflow/truncate"
"github.com/muesli/termenv"
)
const (
// defaultFramerate specifies the maximum interval at which we should
// update the view.
defaultFramerate = time.Second / 60
)
// standardRenderer is a framerate-based terminal renderer, updating the view
// at a given framerate to avoid overloading the terminal emulator.
//
// In cases where very high performance is needed the renderer can be told
// to exclude ranges of lines, allowing them to be written to directly.
type standardRenderer struct {
mtx *sync.Mutex
out *termenv.Output
buf bytes.Buffer
queuedMessageLines []string
framerate time.Duration
ticker *time.Ticker
done chan struct{}
lastRender string
linesRendered int
useANSICompressor bool
once sync.Once
// cursor visibility state
cursorHidden bool
// essentially whether or not we're using the full size of the terminal
altScreenActive bool
// renderer dimensions; usually the size of the window
width int
height int
// lines explicitly set not to render
ignoreLines map[int]struct{}
}
// newRenderer creates a new renderer. Normally you'll want to initialize it
// with os.Stdout as the first argument.
func newRenderer(out *termenv.Output, useANSICompressor bool) renderer {
r := &standardRenderer{
out: out,
mtx: &sync.Mutex{},
done: make(chan struct{}),
framerate: defaultFramerate,
useANSICompressor: useANSICompressor,
queuedMessageLines: []string{},
}
if r.useANSICompressor {
r.out = termenv.NewOutput(&compressor.Writer{Forward: out})
}
return r
}
// start starts the renderer.
func (r *standardRenderer) start() {
if r.ticker == nil {
r.ticker = time.NewTicker(r.framerate)
} else {
// If the ticker already exists, it has been stopped and we need to
// reset it.
r.ticker.Reset(r.framerate)
}
// Since the renderer can be restarted after a stop, we need to reset
// the done channel and its corresponding sync.Once.
r.once = sync.Once{}
go r.listen()
}
// stop permanently halts the renderer, rendering the final frame.
func (r *standardRenderer) stop() {
// flush locks the mutex
r.flush()
r.mtx.Lock()
defer r.mtx.Unlock()
r.out.ClearLine()
r.once.Do(func() {
r.done <- struct{}{}
})
if r.useANSICompressor {
if w, ok := r.out.Writer().(io.WriteCloser); ok {
_ = w.Close()
}
}
}
// kill halts the renderer. The final frame will not be rendered.
func (r *standardRenderer) kill() {
r.mtx.Lock()
defer r.mtx.Unlock()
r.out.ClearLine()
r.once.Do(func() {
r.done <- struct{}{}
})
}
// listen waits for ticks on the ticker, or a signal to stop the renderer.
func (r *standardRenderer) listen() {
for {
select {
case <-r.done:
r.ticker.Stop()
return
case <-r.ticker.C:
r.flush()
}
}
}
// flush renders the buffer.
func (r *standardRenderer) flush() {
r.mtx.Lock()
defer r.mtx.Unlock()
if r.buf.Len() == 0 || r.buf.String() == r.lastRender {
// Nothing to do
return
}
// Output buffer
buf := &bytes.Buffer{}
out := termenv.NewOutput(buf)
newLines := strings.Split(r.buf.String(), "\n")
// If we know the output's height, we can use it to determine how many
// lines we can render. We drop lines from the top of the render buffer if
// necessary, as we can't navigate the cursor into the terminal's scrollback
// buffer.
if r.height > 0 && len(newLines) > r.height {
newLines = newLines[len(newLines)-r.height:]
}
numLinesThisFlush := len(newLines)
oldLines := strings.Split(r.lastRender, "\n")
skipLines := make(map[int]struct{})
flushQueuedMessages := len(r.queuedMessageLines) > 0 && !r.altScreenActive
// Add any queued messages to this render
if flushQueuedMessages {
newLines = append(r.queuedMessageLines, newLines...)
r.queuedMessageLines = []string{}
}
// Clear any lines we painted in the last render.
if r.linesRendered > 0 {
for i := r.linesRendered - 1; i > 0; i-- {
// If the number of lines we want to render hasn't increased and
// new line is the same as the old line we can skip rendering for
// this line as a performance optimization.
if (len(newLines) <= len(oldLines)) && (len(newLines) > i && len(oldLines) > i) && (newLines[i] == oldLines[i]) {
skipLines[i] = struct{}{}
} else if _, exists := r.ignoreLines[i]; !exists {
out.ClearLine()
}
out.CursorUp(1)
}
if _, exists := r.ignoreLines[0]; !exists {
// We need to return to the start of the line here to properly
// erase it. Going back the entire width of the terminal will
// usually be farther than we need to go, but terminal emulators
// will stop the cursor at the start of the line as a rule.
//
// We use this sequence in particular because it's part of the ANSI
// standard (whereas others are proprietary to, say, VT100/VT52).
// If cursor previous line (ESC[ + <n> + F) were better supported
// we could use that above to eliminate this step.
out.CursorBack(r.width)
out.ClearLine()
}
}
// Merge the set of lines we're skipping as a rendering optimization with
// the set of lines we've explicitly asked the renderer to ignore.
if r.ignoreLines != nil {
for k, v := range r.ignoreLines {
skipLines[k] = v
}
}
// Paint new lines
for i := 0; i < len(newLines); i++ {
if _, skip := skipLines[i]; skip {
// Unless this is the last line, move the cursor down.
if i < len(newLines)-1 {
out.CursorDown(1)
}
} else {
line := newLines[i]
// Truncate lines wider than the width of the window to avoid
// wrapping, which will mess up rendering. If we don't have the
// width of the window this will be ignored.
//
// Note that on Windows we only get the width of the window on
// program initialization, so after a resize this won't perform
// correctly (signal SIGWINCH is not supported on Windows).
if r.width > 0 {
line = truncate.String(line, uint(r.width))
}
_, _ = out.WriteString(line)
if i < len(newLines)-1 {
_, _ = out.WriteString("\r\n")
}
}
}
r.linesRendered = numLinesThisFlush
// Make sure the cursor is at the start of the last line to keep rendering
// behavior consistent.
if r.altScreenActive {
// This case fixes a bug in macOS terminal. In other terminals the
// other case seems to do the job regardless of whether or not we're
// using the full terminal window.
out.MoveCursor(r.linesRendered, 0)
} else {
out.CursorBack(r.width)
}
_, _ = r.out.Write(buf.Bytes())
r.lastRender = r.buf.String()
r.buf.Reset()
}
// write writes to the internal buffer. The buffer will be outputted via the
// ticker which calls flush().
func (r *standardRenderer) write(s string) {
r.mtx.Lock()
defer r.mtx.Unlock()
r.buf.Reset()
// If an empty string was passed we should clear existing output and
// rendering nothing. Rather than introduce additional state to manage
// this, we render a single space as a simple (albeit less correct)
// solution.
if s == "" {
s = " "
}
_, _ = r.buf.WriteString(s)
}
func (r *standardRenderer) repaint() {
r.lastRender = ""
}
func (r *standardRenderer) clearScreen() {
r.mtx.Lock()
defer r.mtx.Unlock()
r.out.ClearScreen()
r.out.MoveCursor(1, 1)
r.repaint()
}
func (r *standardRenderer) altScreen() bool {
r.mtx.Lock()
defer r.mtx.Unlock()
return r.altScreenActive
}
func (r *standardRenderer) enterAltScreen() {
r.mtx.Lock()
defer r.mtx.Unlock()
if r.altScreenActive {
return
}
r.altScreenActive = true
r.out.AltScreen()
// Ensure that the terminal is cleared, even when it doesn't support
// alt screen (or alt screen support is disabled, like GNU screen by
// default).
//
// Note: we can't use r.clearScreen() here because the mutex is already
// locked.
r.out.ClearScreen()
r.out.MoveCursor(1, 1)
// cmd.exe and other terminals keep separate cursor states for the AltScreen
// and the main buffer. We have to explicitly reset the cursor visibility
// whenever we enter AltScreen.
if r.cursorHidden {
r.out.HideCursor()
} else {
r.out.ShowCursor()
}
r.repaint()
}
func (r *standardRenderer) exitAltScreen() {
r.mtx.Lock()
defer r.mtx.Unlock()
if !r.altScreenActive {
return
}
r.altScreenActive = false
r.out.ExitAltScreen()
// cmd.exe and other terminals keep separate cursor states for the AltScreen
// and the main buffer. We have to explicitly reset the cursor visibility
// whenever we exit AltScreen.
if r.cursorHidden {
r.out.HideCursor()
} else {
r.out.ShowCursor()
}
r.repaint()
}
func (r *standardRenderer) showCursor() {
r.mtx.Lock()
defer r.mtx.Unlock()
r.cursorHidden = false
r.out.ShowCursor()
}
func (r *standardRenderer) hideCursor() {
r.mtx.Lock()
defer r.mtx.Unlock()
r.cursorHidden = true
r.out.HideCursor()
}
func (r *standardRenderer) enableMouseCellMotion() {
r.mtx.Lock()
defer r.mtx.Unlock()
r.out.EnableMouseCellMotion()
}
func (r *standardRenderer) disableMouseCellMotion() {
r.mtx.Lock()
defer r.mtx.Unlock()
r.out.DisableMouseCellMotion()
}
func (r *standardRenderer) enableMouseAllMotion() {
r.mtx.Lock()
defer r.mtx.Unlock()
r.out.EnableMouseAllMotion()
}
func (r *standardRenderer) disableMouseAllMotion() {
r.mtx.Lock()
defer r.mtx.Unlock()
r.out.DisableMouseAllMotion()
}
// setIgnoredLines specifies lines not to be touched by the standard Bubble Tea
// renderer.
func (r *standardRenderer) setIgnoredLines(from int, to int) {
// Lock if we're going to be clearing some lines since we don't want
// anything jacking our cursor.
if r.linesRendered > 0 {
r.mtx.Lock()
defer r.mtx.Unlock()
}
if r.ignoreLines == nil {
r.ignoreLines = make(map[int]struct{})
}
for i := from; i < to; i++ {
r.ignoreLines[i] = struct{}{}
}
// Erase ignored lines
if r.linesRendered > 0 {
buf := &bytes.Buffer{}
out := termenv.NewOutput(buf)
for i := r.linesRendered - 1; i >= 0; i-- {
if _, exists := r.ignoreLines[i]; exists {
out.ClearLine()
}
out.CursorUp(1)
}
out.MoveCursor(r.linesRendered, 0) // put cursor back
_, _ = r.out.Write(buf.Bytes())
}
}
// clearIgnoredLines returns control of any ignored lines to the standard
// Bubble Tea renderer. That is, any lines previously set to be ignored can be
// rendered to again.
func (r *standardRenderer) clearIgnoredLines() {
r.ignoreLines = nil
}
// insertTop effectively scrolls up. It inserts lines at the top of a given
// area designated to be a scrollable region, pushing everything else down.
// This is roughly how ncurses does it.
//
// To call this function use command ScrollUp().
//
// For this to work renderer.ignoreLines must be set to ignore the scrollable
// region since we are bypassing the normal Bubble Tea renderer here.
//
// Because this method relies on the terminal dimensions, it's only valid for
// full-window applications (generally those that use the alternate screen
// buffer).
//
// This method bypasses the normal rendering buffer and is philosophically
// different than the normal way we approach rendering in Bubble Tea. It's for
// use in high-performance rendering, such as a pager that could potentially
// be rendering very complicated ansi. In cases where the content is simpler
// standard Bubble Tea rendering should suffice.
func (r *standardRenderer) insertTop(lines []string, topBoundary, bottomBoundary int) {
r.mtx.Lock()
defer r.mtx.Unlock()
buf := &bytes.Buffer{}
out := termenv.NewOutput(buf)
out.ChangeScrollingRegion(topBoundary, bottomBoundary)
out.MoveCursor(topBoundary, 0)
out.InsertLines(len(lines))
_, _ = out.WriteString(strings.Join(lines, "\r\n"))
out.ChangeScrollingRegion(0, r.height)
// Move cursor back to where the main rendering routine expects it to be
out.MoveCursor(r.linesRendered, 0)
_, _ = r.out.Write(buf.Bytes())
}
// insertBottom effectively scrolls down. It inserts lines at the bottom of
// a given area designated to be a scrollable region, pushing everything else
// up. This is roughly how ncurses does it.
//
// To call this function use the command ScrollDown().
//
// See note in insertTop() for caveats, how this function only makes sense for
// full-window applications, and how it differs from the normal way we do
// rendering in Bubble Tea.
func (r *standardRenderer) insertBottom(lines []string, topBoundary, bottomBoundary int) {
r.mtx.Lock()
defer r.mtx.Unlock()
buf := &bytes.Buffer{}
out := termenv.NewOutput(buf)
out.ChangeScrollingRegion(topBoundary, bottomBoundary)
out.MoveCursor(bottomBoundary, 0)
_, _ = out.WriteString("\r\n" + strings.Join(lines, "\r\n"))
out.ChangeScrollingRegion(0, r.height)
// Move cursor back to where the main rendering routine expects it to be
out.MoveCursor(r.linesRendered, 0)
_, _ = r.out.Write(buf.Bytes())
}
// handleMessages handles internal messages for the renderer.
func (r *standardRenderer) handleMessages(msg Msg) {
switch msg := msg.(type) {
case repaintMsg:
// Force a repaint by clearing the render cache as we slide into a
// render.
r.mtx.Lock()
r.repaint()
r.mtx.Unlock()
case WindowSizeMsg:
r.mtx.Lock()
r.width = msg.Width
r.height = msg.Height
r.repaint()
r.mtx.Unlock()
case clearScrollAreaMsg:
r.clearIgnoredLines()
// Force a repaint on the area where the scrollable stuff was in this
// update cycle
r.mtx.Lock()
r.repaint()
r.mtx.Unlock()
case syncScrollAreaMsg:
// Re-render scrolling area
r.clearIgnoredLines()
r.setIgnoredLines(msg.topBoundary, msg.bottomBoundary)
r.insertTop(msg.lines, msg.topBoundary, msg.bottomBoundary)
// Force non-scrolling stuff to repaint in this update cycle
r.mtx.Lock()
r.repaint()
r.mtx.Unlock()
case scrollUpMsg:
r.insertTop(msg.lines, msg.topBoundary, msg.bottomBoundary)
case scrollDownMsg:
r.insertBottom(msg.lines, msg.topBoundary, msg.bottomBoundary)
case printLineMessage:
if !r.altScreenActive {
lines := strings.Split(msg.messageBody, "\n")
r.mtx.Lock()
r.queuedMessageLines = append(r.queuedMessageLines, lines...)
r.repaint()
r.mtx.Unlock()
}
}
}
// HIGH-PERFORMANCE RENDERING STUFF
type syncScrollAreaMsg struct {
lines []string
topBoundary int
bottomBoundary int
}
// SyncScrollArea performs a paint of the entire region designated to be the
// scrollable area. This is required to initialize the scrollable region and
// should also be called on resize (WindowSizeMsg).
//
// For high-performance, scroll-based rendering only.
func SyncScrollArea(lines []string, topBoundary int, bottomBoundary int) Cmd {
return func() Msg {
return syncScrollAreaMsg{
lines: lines,
topBoundary: topBoundary,
bottomBoundary: bottomBoundary,
}
}
}
type clearScrollAreaMsg struct{}
// ClearScrollArea deallocates the scrollable region and returns the control of
// those lines to the main rendering routine.
//
// For high-performance, scroll-based rendering only.
func ClearScrollArea() Msg {
return clearScrollAreaMsg{}
}
type scrollUpMsg struct {
lines []string
topBoundary int
bottomBoundary int
}
// ScrollUp adds lines to the top of the scrollable region, pushing existing
// lines below down. Lines that are pushed out the scrollable region disappear
// from view.
//
// For high-performance, scroll-based rendering only.
func ScrollUp(newLines []string, topBoundary, bottomBoundary int) Cmd {
return func() Msg {
return scrollUpMsg{
lines: newLines,
topBoundary: topBoundary,
bottomBoundary: bottomBoundary,
}
}
}
type scrollDownMsg struct {
lines []string
topBoundary int
bottomBoundary int
}
// ScrollDown adds lines to the bottom of the scrollable region, pushing
// existing lines above up. Lines that are pushed out of the scrollable region
// disappear from view.
//
// For high-performance, scroll-based rendering only.
func ScrollDown(newLines []string, topBoundary, bottomBoundary int) Cmd {
return func() Msg {
return scrollDownMsg{
lines: newLines,
topBoundary: topBoundary,
bottomBoundary: bottomBoundary,
}
}
}
type printLineMessage struct {
messageBody string
}
// Println prints above the Program. This output is unmanaged by the program and
// will persist across renders by the Program.
//
// Unlike fmt.Println (but similar to log.Println) the message will be print on
// its own line.
//
// If the altscreen is active no output will be printed.
func Println(args ...interface{}) Cmd {
return func() Msg {
return printLineMessage{
messageBody: fmt.Sprint(args...),
}
}
}
// Printf prints above the Program. It takes a format template followed by
// values similar to fmt.Printf. This output is unmanaged by the program and
// will persist across renders by the Program.
//
// Unlike fmt.Printf (but similar to log.Printf) the message will be print on
// its own line.
//
// If the altscreen is active no output will be printed.
func Printf(template string, args ...interface{}) Cmd {
return func() Msg {
return printLineMessage{
messageBody: fmt.Sprintf(template, args...),
}
}
}