// SPDX-License-Identifier: Unlicense OR MIT package widget import ( "bufio" "bytes" "image" "io" "math" "runtime" "sort" "strings" "time" "unicode" "unicode/utf8" "gioui.org/f32" "gioui.org/gesture" "gioui.org/io/clipboard" "gioui.org/io/event" "gioui.org/io/key" "gioui.org/io/pointer" "gioui.org/layout" "gioui.org/op" "gioui.org/op/clip" "gioui.org/op/paint" "gioui.org/text" "gioui.org/unit" "golang.org/x/image/math/fixed" ) // Editor implements an editable and scrollable text area. type Editor struct { Alignment text.Alignment // SingleLine force the text to stay on a single line. // SingleLine also sets the scrolling direction to // horizontal. SingleLine bool // Submit enabled translation of carriage return keys to SubmitEvents. // If not enabled, carriage returns are inserted as newlines in the text. Submit bool // Mask replaces the visual display of each rune in the contents with the given rune. // Newline characters are not masked. When non-zero, the unmasked contents // are accessed by Len, Text, and SetText. Mask rune // InputHint specifies the type of on-screen keyboard to be displayed. InputHint key.InputHint eventKey int font text.Font shaper text.Shaper textSize fixed.Int26_6 blinkStart time.Time focused bool rr editBuffer maskReader maskReader lastMask rune maxWidth int viewSize image.Point valid bool lines []text.Line shapes []line dims layout.Dimensions requestFocus bool // index tracks combined caret positions at regularly // spaced intervals to speed up caret seeking. index []combinedPos // ime tracks the state relevant to input methods. ime struct { imeState scratch []byte } caret struct { on bool scroll bool // xoff is the offset to the current position when moving between lines. xoff fixed.Int26_6 // start is the current caret position in runes, and also the start position of // selected text. end is the end position of selected text. If start // == end, then there's no selection. Note that it's possible (and // common) that the caret (start) is after the end, e.g. after // Shift-DownArrow. start int end int } dragging bool dragger gesture.Drag scroller gesture.Scroll scrollOff image.Point clicker gesture.Click // events is the list of events not yet processed. events []EditorEvent // prevEvents is the number of events from the previous frame. prevEvents int } type imeState struct { selection struct { rng key.Range caret key.Caret } snippet key.Snippet start, end int } type maskReader struct { // rr is the underlying reader. rr io.RuneReader maskBuf [utf8.UTFMax]byte // mask is the utf-8 encoded mask rune. mask []byte // overflow contains excess mask bytes left over after the last Read call. overflow []byte } // combinedPos is a point in the editor. type combinedPos struct { // ofs is the offset into the editorBuffer in bytes. The other three fields are based off of this one. ofs int // runes is the offset in runes. runes int // lineCol.Y = line (offset into Editor.lines), and X = col (offset into // Editor.lines[Y]) lineCol screenPos // Pixel coordinates x fixed.Int26_6 y int } type selectionAction int const ( selectionExtend selectionAction = iota selectionClear ) func (m *maskReader) Reset(r io.RuneReader, mr rune) { m.rr = r n := utf8.EncodeRune(m.maskBuf[:], mr) m.mask = m.maskBuf[:n] } // Read reads from the underlying reader and replaces every // rune with the mask rune. func (m *maskReader) Read(b []byte) (n int, err error) { for len(b) > 0 { var replacement []byte if len(m.overflow) > 0 { replacement = m.overflow } else { var r rune r, _, err = m.rr.ReadRune() if err != nil { break } if r == '\n' { replacement = []byte{'\n'} } else { replacement = m.mask } } nn := copy(b, replacement) m.overflow = replacement[nn:] n += nn b = b[nn:] } return n, err } type EditorEvent interface { isEditorEvent() } // A ChangeEvent is generated for every user change to the text. type ChangeEvent struct{} // A SubmitEvent is generated when Submit is set // and a carriage return key is pressed. type SubmitEvent struct { Text string } // A SelectEvent is generated when the user selects some text, or changes the // selection (e.g. with a shift-click), including if they remove the // selection. The selected text is not part of the event, on the theory that // it could be a relatively expensive operation (for a large editor), most // applications won't actually care about it, and those that do can call // Editor.SelectedText() (which can be empty). type SelectEvent struct{} type line struct { offset image.Point clip clip.Op selected bool selectionYOffs int selectionSize image.Point } const ( blinksPerSecond = 1 maxBlinkDuration = 10 * time.Second ) // Events returns available editor events. func (e *Editor) Events() []EditorEvent { events := e.events e.events = nil e.prevEvents = 0 return events } func (e *Editor) processEvents(gtx layout.Context) { // Flush events from before the previous Layout. n := copy(e.events, e.events[e.prevEvents:]) e.events = e.events[:n] e.prevEvents = n if e.shaper == nil { // Can't process events without a shaper. return } oldStart, oldLen := min(e.caret.start, e.caret.end), e.SelectionLen() e.processPointer(gtx) e.processKey(gtx) // Queue a SelectEvent if the selection changed, including if it went away. if newStart, newLen := min(e.caret.start, e.caret.end), e.SelectionLen(); oldStart != newStart || oldLen != newLen { e.events = append(e.events, SelectEvent{}) } } func (e *Editor) makeValid() { if e.valid { return } e.lines, e.dims = e.layoutText(e.shaper) e.valid = true } func (e *Editor) processPointer(gtx layout.Context) { sbounds := e.scrollBounds() var smin, smax int var axis gesture.Axis if e.SingleLine { axis = gesture.Horizontal smin, smax = sbounds.Min.X, sbounds.Max.X } else { axis = gesture.Vertical smin, smax = sbounds.Min.Y, sbounds.Max.Y } sdist := e.scroller.Scroll(gtx.Metric, gtx, gtx.Now, axis) var soff int if e.SingleLine { e.scrollRel(sdist, 0) soff = e.scrollOff.X } else { e.scrollRel(0, sdist) soff = e.scrollOff.Y } for _, evt := range e.clickDragEvents(gtx) { switch evt := evt.(type) { case gesture.ClickEvent: switch { case evt.Type == gesture.TypePress && evt.Source == pointer.Mouse, evt.Type == gesture.TypeClick: prevCaretPos := e.caret.start e.blinkStart = gtx.Now e.moveCoord(image.Point{ X: int(math.Round(float64(evt.Position.X))), Y: int(math.Round(float64(evt.Position.Y))), }) e.requestFocus = true if e.scroller.State() != gesture.StateFlinging { e.caret.scroll = true } if evt.Modifiers == key.ModShift { // If they clicked closer to the end, then change the end to // where the caret used to be (effectively swapping start & end). if abs(e.caret.end-e.caret.start) < abs(e.caret.start-prevCaretPos) { e.caret.end = prevCaretPos } } else { e.ClearSelection() } e.dragging = true // Process a double-click. if evt.NumClicks == 2 { e.moveWord(-1, selectionClear) e.moveWord(1, selectionExtend) e.dragging = false } } case pointer.Event: release := false switch { case evt.Type == pointer.Release && evt.Source == pointer.Mouse: release = true fallthrough case evt.Type == pointer.Drag && evt.Source == pointer.Mouse: if e.dragging { e.blinkStart = gtx.Now e.moveCoord(image.Point{ X: int(math.Round(float64(evt.Position.X))), Y: int(math.Round(float64(evt.Position.Y))), }) e.caret.scroll = true if release { e.dragging = false } } } } } if (sdist > 0 && soff >= smax) || (sdist < 0 && soff <= smin) { e.scroller.Stop() } } func (e *Editor) clickDragEvents(gtx layout.Context) []event.Event { var combinedEvents []event.Event for _, evt := range e.clicker.Events(gtx) { combinedEvents = append(combinedEvents, evt) } for _, evt := range e.dragger.Events(gtx.Metric, gtx, gesture.Both) { combinedEvents = append(combinedEvents, evt) } return combinedEvents } func (e *Editor) processKey(gtx layout.Context) { if e.rr.Changed() { e.events = append(e.events, ChangeEvent{}) } for _, ke := range gtx.Events(&e.eventKey) { e.blinkStart = gtx.Now switch ke := ke.(type) { case key.FocusEvent: e.focused = ke.Focus // Reset IME state. e.ime.imeState = imeState{} case key.Event: if !e.focused || ke.State != key.Press { break } if e.Submit && (ke.Name == key.NameReturn || ke.Name == key.NameEnter) { if !ke.Modifiers.Contain(key.ModShift) { e.events = append(e.events, SubmitEvent{ Text: e.Text(), }) continue } } if e.command(gtx, ke) { e.caret.scroll = true e.scroller.Stop() } case key.SnippetEvent: e.updateSnippet(gtx, ke.Start, ke.End) case key.EditEvent: e.caret.scroll = true e.scroller.Stop() e.replace(ke.Range.Start, ke.Range.End, ke.Text) e.caret.xoff = 0 // Complete a paste event, initiated by Shortcut-V in Editor.command(). case clipboard.Event: e.caret.scroll = true e.scroller.Stop() e.append(ke.Text) case key.SelectionEvent: e.caret.scroll = true e.scroller.Stop() e.caret.start = e.closestPosition(combinedPos{runes: ke.Start}).runes e.caret.end = e.closestPosition(combinedPos{runes: ke.End}).runes } if e.rr.Changed() { e.events = append(e.events, ChangeEvent{}) } } } func (e *Editor) moveLines(distance int, selAct selectionAction) { caretStart := e.closestPosition(combinedPos{runes: e.caret.start}) x := caretStart.x + e.caret.xoff // Seek to line. pos := e.closestPosition(combinedPos{lineCol: screenPos{Y: caretStart.lineCol.Y + distance}}) pos = e.closestPosition(combinedPos{x: x, y: pos.y}) e.caret.start = pos.runes e.caret.xoff = x - pos.x e.updateSelection(selAct) } func (e *Editor) command(gtx layout.Context, k key.Event) bool { modSkip := key.ModCtrl if runtime.GOOS == "darwin" { modSkip = key.ModAlt } moveByWord := k.Modifiers.Contain(modSkip) selAct := selectionClear if k.Modifiers.Contain(key.ModShift) { selAct = selectionExtend } switch k.Name { case key.NameReturn, key.NameEnter: e.append("\n") case key.NameDeleteBackward: if moveByWord { e.deleteWord(-1) } else { e.Delete(-1) } case key.NameDeleteForward: if moveByWord { e.deleteWord(1) } else { e.Delete(1) } case key.NameUpArrow: e.moveLines(-1, selAct) case key.NameDownArrow: e.moveLines(+1, selAct) case key.NameLeftArrow: if moveByWord { e.moveWord(-1, selAct) } else { if selAct == selectionClear { e.ClearSelection() } e.MoveCaret(-1, -1*int(selAct)) } case key.NameRightArrow: if moveByWord { e.moveWord(1, selAct) } else { if selAct == selectionClear { e.ClearSelection() } e.MoveCaret(1, int(selAct)) } case key.NamePageUp: e.movePages(-1, selAct) case key.NamePageDown: e.movePages(+1, selAct) case key.NameHome: e.moveStart(selAct) case key.NameEnd: e.moveEnd(selAct) // Initiate a paste operation, by requesting the clipboard contents; other // half is in Editor.processKey() under clipboard.Event. case "V": if k.Modifiers != key.ModShortcut { return false } clipboard.ReadOp{Tag: &e.eventKey}.Add(gtx.Ops) // Copy or Cut selection -- ignored if nothing selected. case "C", "X": if k.Modifiers != key.ModShortcut { return false } if text := e.SelectedText(); text != "" { clipboard.WriteOp{Text: text}.Add(gtx.Ops) if k.Name == "X" { e.Delete(1) } } // Select all case "A": if k.Modifiers != key.ModShortcut { return false } e.caret.end = 0 e.caret.start = e.Len() default: return false } return true } // Focus requests the input focus for the Editor. func (e *Editor) Focus() { e.requestFocus = true } // Focused returns whether the editor is focused or not. func (e *Editor) Focused() bool { return e.focused } // Layout lays out the editor. If content is not nil, it is laid out on top. func (e *Editor) Layout(gtx layout.Context, sh text.Shaper, font text.Font, size unit.Value, content layout.Widget) layout.Dimensions { textSize := fixed.I(gtx.Px(size)) if e.font != font || e.textSize != textSize { e.invalidate() e.font = font e.textSize = textSize } maxWidth := gtx.Constraints.Max.X if e.SingleLine { maxWidth = inf } if maxWidth != e.maxWidth { e.maxWidth = maxWidth e.invalidate() } if sh != e.shaper { e.shaper = sh e.invalidate() } if e.Mask != e.lastMask { e.lastMask = e.Mask e.invalidate() } e.makeValid() e.processEvents(gtx) e.makeValid() if viewSize := gtx.Constraints.Constrain(e.dims.Size); viewSize != e.viewSize { e.viewSize = viewSize e.invalidate() } e.makeValid() dims := e.layout(gtx, content) if e.focused { // Notify IME of selection if it changed. newSel := e.ime.selection newSel.rng = key.Range{ Start: e.caret.start, End: e.caret.end, } caretPos, carAsc, carDesc := e.caretInfo() newSel.caret = key.Caret{ Pos: layout.FPt(caretPos), Ascent: float32(carAsc), Descent: float32(carDesc), } if newSel != e.ime.selection { e.ime.selection = newSel key.SelectionOp{ Tag: &e.eventKey, Range: newSel.rng, Caret: newSel.caret, }.Add(gtx.Ops) } e.updateSnippet(gtx, e.ime.start, e.ime.end) } return dims } // updateSnippet adds a key.SnippetOp if the snippet content or position // have changed. off and len are in runes. func (e *Editor) updateSnippet(gtx layout.Context, start, end int) { if start > end { start, end = end, start } imeStart := e.closestPosition(combinedPos{runes: start}) imeEnd := e.closestPosition(combinedPos{runes: end}) e.ime.start = imeStart.runes e.ime.end = imeEnd.runes e.rr.Seek(int64(imeStart.ofs), io.SeekStart) n := imeEnd.ofs - imeStart.ofs if n > len(e.ime.scratch) { e.ime.scratch = make([]byte, n) } scratch := e.ime.scratch[:n] read, _ := e.rr.Read(scratch) if read != len(scratch) { panic("e.rr.Read truncated data") } newSnip := key.Snippet{ Range: key.Range{ Start: e.ime.start, End: e.ime.end, }, Text: e.ime.snippet.Text, } if string(scratch) != newSnip.Text { newSnip.Text = string(scratch) } if newSnip == e.ime.snippet { return } e.ime.snippet = newSnip key.SnippetOp{ Tag: &e.eventKey, Snippet: newSnip, }.Add(gtx.Ops) } func (e *Editor) layout(gtx layout.Context, content layout.Widget) layout.Dimensions { // Adjust scrolling for new viewport and layout. e.scrollRel(0, 0) if e.caret.scroll { e.caret.scroll = false e.scrollToCaret() } off := image.Point{ X: -e.scrollOff.X, Y: -e.scrollOff.Y, } cl := textPadding(e.lines) cl.Max = cl.Max.Add(e.viewSize) caretStart := e.closestPosition(combinedPos{runes: e.caret.start}) caretEnd := e.closestPosition(combinedPos{runes: e.caret.end}) startSel, endSel := sortPoints(caretStart.lineCol, caretEnd.lineCol) it := segmentIterator{ startSel: startSel, endSel: endSel, Lines: e.lines, Clip: cl, Alignment: e.Alignment, Width: e.viewSize.X, Offset: off, } e.shapes = e.shapes[:0] for { layout, off, selected, yOffs, size, ok := it.Next() if !ok { break } op := clip.Outline{Path: e.shaper.Shape(e.font, e.textSize, layout)}.Op() e.shapes = append(e.shapes, line{off, op, selected, yOffs, size}) } key.InputOp{Tag: &e.eventKey, Hint: e.InputHint}.Add(gtx.Ops) if e.requestFocus { key.FocusOp{Tag: &e.eventKey}.Add(gtx.Ops) key.SoftKeyboardOp{Show: true}.Add(gtx.Ops) } e.requestFocus = false pointerPadding := gtx.Px(unit.Dp(4)) r := image.Rectangle{Max: e.viewSize} r.Min.X -= pointerPadding r.Min.Y -= pointerPadding r.Max.X += pointerPadding r.Max.X += pointerPadding defer clip.Rect(r).Push(gtx.Ops).Pop() pointer.CursorNameOp{Name: pointer.CursorText}.Add(gtx.Ops) var scrollRange image.Rectangle if e.SingleLine { scrollRange.Min.X = min(-e.scrollOff.X, 0) scrollRange.Max.X = max(0, e.dims.Size.X-(e.scrollOff.X+e.viewSize.X)) } else { scrollRange.Min.Y = -e.scrollOff.Y scrollRange.Max.Y = max(0, e.dims.Size.Y-(e.scrollOff.Y+e.viewSize.Y)) } e.scroller.Add(gtx.Ops, scrollRange) e.clicker.Add(gtx.Ops) e.dragger.Add(gtx.Ops) e.caret.on = false if e.focused { now := gtx.Now dt := now.Sub(e.blinkStart) blinking := dt < maxBlinkDuration const timePerBlink = time.Second / blinksPerSecond nextBlink := now.Add(timePerBlink/2 - dt%(timePerBlink/2)) if blinking { redraw := op.InvalidateOp{At: nextBlink} redraw.Add(gtx.Ops) } e.caret.on = e.focused && (!blinking || dt%timePerBlink < timePerBlink/2) } if content != nil { content(gtx) } return layout.Dimensions{Size: e.viewSize, Baseline: e.dims.Baseline} } // PaintSelection paints the contrasting background for selected text. func (e *Editor) PaintSelection(gtx layout.Context) { cl := textPadding(e.lines) cl.Max = cl.Max.Add(e.viewSize) defer clip.Rect(cl).Push(gtx.Ops).Pop() for _, shape := range e.shapes { if !shape.selected { continue } offset := shape.offset offset.Y += shape.selectionYOffs t := op.Offset(layout.FPt(offset)).Push(gtx.Ops) cl := clip.Rect(image.Rectangle{Max: shape.selectionSize}).Push(gtx.Ops) paint.PaintOp{}.Add(gtx.Ops) cl.Pop() t.Pop() } } func (e *Editor) PaintText(gtx layout.Context) { cl := textPadding(e.lines) cl.Max = cl.Max.Add(e.viewSize) defer clip.Rect(cl).Push(gtx.Ops).Pop() for _, shape := range e.shapes { t := op.Offset(layout.FPt(shape.offset)).Push(gtx.Ops) cl := shape.clip.Push(gtx.Ops) paint.PaintOp{}.Add(gtx.Ops) cl.Pop() t.Pop() } } func (e *Editor) PaintCaret(gtx layout.Context) { if !e.caret.on { return } carWidth2 := gtx.Px(unit.Dp(1)) / 2 if carWidth2 < 1 { carWidth2 = 1 } caretPos, carAsc, carDesc := e.caretInfo() carRect := image.Rectangle{ Min: caretPos.Sub(image.Pt(carWidth2, carAsc)), Max: caretPos.Add(image.Pt(carWidth2, carDesc)), } cl := textPadding(e.lines) // Account for caret width to each side. if cl.Max.X < carWidth2 { cl.Max.X = carWidth2 } if cl.Min.X > -carWidth2 { cl.Min.X = -carWidth2 } cl.Max = cl.Max.Add(e.viewSize) carRect = cl.Intersect(carRect) if !carRect.Empty() { defer clip.Rect(carRect).Push(gtx.Ops).Pop() paint.PaintOp{}.Add(gtx.Ops) } } func (e *Editor) caretInfo() (pos image.Point, ascent, descent int) { caretStart := e.closestPosition(combinedPos{runes: e.caret.start}) carX := caretStart.x carY := caretStart.y ascent = -e.lines[caretStart.lineCol.Y].Bounds.Min.Y.Ceil() descent = e.lines[caretStart.lineCol.Y].Bounds.Max.Y.Ceil() pos = image.Point{ X: carX.Round(), Y: carY, } pos = pos.Sub(e.scrollOff) return } // TODO: copied from package math. Remove when Go 1.18 is minimum. const ( intSize = 32 << (^uint(0) >> 63) // 32 or 64 maxInt = 1<<(intSize-1) - 1 ) // Len is the length of the editor contents, in runes. func (e *Editor) Len() int { end := e.closestPosition(combinedPos{runes: maxInt}) return end.runes } // Text returns the contents of the editor. func (e *Editor) Text() string { return e.rr.String() } // SetText replaces the contents of the editor, clearing any selection first. func (e *Editor) SetText(s string) { e.rr = editBuffer{} e.caret.start = 0 e.caret.end = 0 e.replace(e.caret.start, e.caret.end, s) e.caret.xoff = 0 } func (e *Editor) scrollBounds() image.Rectangle { var b image.Rectangle if e.SingleLine { if len(e.lines) > 0 { b.Min.X = align(e.Alignment, e.lines[0].Width, e.viewSize.X).Floor() if b.Min.X > 0 { b.Min.X = 0 } } b.Max.X = e.dims.Size.X + b.Min.X - e.viewSize.X } else { b.Max.Y = e.dims.Size.Y - e.viewSize.Y } return b } func (e *Editor) scrollRel(dx, dy int) { e.scrollAbs(e.scrollOff.X+dx, e.scrollOff.Y+dy) } func (e *Editor) scrollAbs(x, y int) { e.scrollOff.X = x e.scrollOff.Y = y b := e.scrollBounds() if e.scrollOff.X > b.Max.X { e.scrollOff.X = b.Max.X } if e.scrollOff.X < b.Min.X { e.scrollOff.X = b.Min.X } if e.scrollOff.Y > b.Max.Y { e.scrollOff.Y = b.Max.Y } if e.scrollOff.Y < b.Min.Y { e.scrollOff.Y = b.Min.Y } } func (e *Editor) moveCoord(pos image.Point) { x := fixed.I(pos.X + e.scrollOff.X) y := pos.Y + e.scrollOff.Y e.caret.start = e.closestPosition(combinedPos{x: x, y: y}).runes e.caret.xoff = 0 } func (e *Editor) layoutText(s text.Shaper) ([]text.Line, layout.Dimensions) { e.rr.Reset() var r io.Reader = &e.rr if e.Mask != 0 { e.maskReader.Reset(&e.rr, e.Mask) r = &e.maskReader } var lines []text.Line if s != nil { lines, _ = s.Layout(e.font, e.textSize, e.maxWidth, r) } else { lines, _ = nullLayout(r) } dims := linesDimens(lines) for i := 0; i < len(lines)-1; i++ { // To avoid layout flickering while editing, assume a soft newline takes // up all available space. if layout := lines[i].Layout; len(layout.Text) > 0 { r := layout.Text[len(layout.Text)-1] if r != '\n' { dims.Size.X = e.maxWidth break } } } return lines, dims } // CaretPos returns the line & column numbers of the caret. func (e *Editor) CaretPos() (line, col int) { caret := e.closestPosition(combinedPos{runes: e.caret.start}) return caret.lineCol.Y, caret.lineCol.X } // CaretCoords returns the coordinates of the caret, relative to the // editor itself. func (e *Editor) CaretCoords() f32.Point { caret := e.closestPosition(combinedPos{runes: e.caret.start}) return f32.Pt(float32(caret.x)/64, float32(caret.y)) } // indexPosition returns the latest position from the index no later than pos. func (e *Editor) indexPosition(pos combinedPos) combinedPos { e.makeValid() // Initialize index with first caret position. if len(e.index) == 0 { l := e.lines[0] e.index = append(e.index, combinedPos{ x: align(e.Alignment, l.Width, e.viewSize.X), y: l.Ascent.Ceil(), }) } i := sort.Search(len(e.index), func(i int) bool { return e.positionGreaterOrEqual(e.index[i], pos) }) // Return position just before pos, which is guaranteed to be less than or equal to pos. if i > 0 { i-- } return e.index[i] } // positionGreaterOrEqual reports whether p1 >= p2 according to the non-zero fields // of p2. All fields of p1 must be a consistent and valid. func (e *Editor) positionGreaterOrEqual(p1, p2 combinedPos) bool { l := e.lines[p1.lineCol.Y] endCol := len(l.Layout.Advances) - 1 if lastLine := p1.lineCol.Y == len(e.lines)-1; lastLine { endCol++ } eol := p1.lineCol.X == endCol switch { case p2.runes != 0: return p1.runes >= p2.runes case p2.lineCol != (screenPos{}): if p1.lineCol.Y != p2.lineCol.Y { return p1.lineCol.Y > p2.lineCol.Y } return eol || p1.lineCol.X >= p2.lineCol.X case p2.x != 0 || p2.y != 0: ly := p1.y + l.Descent.Ceil() prevy := p1.y - l.Ascent.Ceil() switch { case ly < p2.y && p1.lineCol.Y < len(e.lines)-1: // p1 is on a line before p2.y. return false case prevy >= p2.y && p1.lineCol.Y > 0: // p1 is on a line after p2.y. return true } if eol { return true } adv := l.Layout.Advances[p1.lineCol.X] return p1.x+adv-p2.x >= p2.x-p1.x } return true } // closestPosition takes a position and returns its closest valid position. // Zero fields of pos and pos.ofs are ignored. func (e *Editor) closestPosition(pos combinedPos) combinedPos { closest := e.indexPosition(pos) l := e.lines[closest.lineCol.Y] count := 0 const runesPerIndexEntry = 50 // Advance next and prev until next is greater than or equal to pos. for { for ; closest.lineCol.X < len(l.Layout.Advances); closest.lineCol.X++ { if count == runesPerIndexEntry { e.index = append(e.index, closest) count = 0 } count++ if e.positionGreaterOrEqual(closest, pos) { return closest } adv := l.Layout.Advances[closest.lineCol.X] closest.x += adv _, s := e.rr.runeAt(closest.ofs) closest.ofs += s closest.runes++ } if closest.lineCol.Y == len(e.lines)-1 { // End of file. return closest } prevDesc := l.Descent closest.lineCol.Y++ closest.lineCol.X = 0 l = e.lines[closest.lineCol.Y] closest.x = align(e.Alignment, l.Width, e.viewSize.X) closest.y += (prevDesc + l.Ascent).Ceil() } } func (e *Editor) invalidate() { e.index = e.index[:0] e.valid = false } // Delete runes from the caret position. The sign of runes specifies the // direction to delete: positive is forward, negative is backward. // // If there is a selection, it is deleted and counts as a single rune. func (e *Editor) Delete(runes int) { if runes == 0 { return } start := e.caret.start end := e.caret.end if start != end { runes -= sign(runes) } end += runes e.replace(start, end, "") e.caret.xoff = 0 e.ClearSelection() } // Insert inserts text at the caret, moving the caret forward. If there is a // selection, Insert overwrites it. func (e *Editor) Insert(s string) { e.append(s) e.caret.scroll = true } // append inserts s at the cursor, leaving the caret is at the end of s. If // there is a selection, append overwrites it. // xxx|yyy + append zzz => xxxzzz|yyy func (e *Editor) append(s string) { e.replace(e.caret.start, e.caret.end, s) e.caret.xoff = 0 start := e.caret.start if end := e.caret.end; end < start { start = end } e.caret.start = start + utf8.RuneCountInString(s) e.caret.end = e.caret.start } // replace the text between start and end with s. Indices are in runes. func (e *Editor) replace(start, end int, s string) { if e.SingleLine { s = strings.ReplaceAll(s, "\n", " ") } if start > end { start, end = end, start } startPos := e.closestPosition(combinedPos{runes: start}) endPos := e.closestPosition(combinedPos{runes: end}) e.rr.deleteRunes(startPos.ofs, endPos.runes-startPos.runes) e.rr.prepend(startPos.ofs, s) newEnd := startPos.runes + utf8.RuneCountInString(s) adjust := func(pos int) int { switch { case newEnd < pos && pos <= endPos.runes: pos = newEnd case endPos.runes < pos: diff := newEnd - endPos.runes pos = pos + diff } return pos } e.caret.start = adjust(e.caret.start) e.caret.end = adjust(e.caret.end) e.ime.start = adjust(e.ime.start) e.ime.end = adjust(e.ime.end) e.invalidate() } func (e *Editor) movePages(pages int, selAct selectionAction) { caret := e.closestPosition(combinedPos{runes: e.caret.start}) x := caret.x + e.caret.xoff y := caret.y + pages*e.viewSize.Y pos := e.closestPosition(combinedPos{x: x, y: y}) e.caret.start = pos.runes e.caret.xoff = x - pos.x e.updateSelection(selAct) } // MoveCaret moves the caret (aka selection start) and the selection end // relative to their current positions. Positive distances moves forward, // negative distances moves backward. Distances are in runes. func (e *Editor) MoveCaret(startDelta, endDelta int) { e.caret.xoff = 0 e.caret.start = e.closestPosition(combinedPos{runes: e.caret.start + startDelta}).runes e.caret.end = e.closestPosition(combinedPos{runes: e.caret.end + endDelta}).runes } func (e *Editor) moveStart(selAct selectionAction) { caret := e.closestPosition(combinedPos{runes: e.caret.start}) caret = e.closestPosition(combinedPos{lineCol: screenPos{Y: caret.lineCol.Y}}) e.caret.start = caret.runes e.caret.xoff = -caret.x e.updateSelection(selAct) } func (e *Editor) moveEnd(selAct selectionAction) { caret := e.closestPosition(combinedPos{runes: e.caret.start}) caret = e.closestPosition(combinedPos{lineCol: screenPos{X: maxInt, Y: caret.lineCol.Y}}) e.caret.start = caret.runes l := e.lines[caret.lineCol.Y] a := align(e.Alignment, l.Width, e.viewSize.X) e.caret.xoff = l.Width + a - caret.x e.updateSelection(selAct) } // moveWord moves the caret to the next word in the specified direction. // Positive is forward, negative is backward. // Absolute values greater than one will skip that many words. func (e *Editor) moveWord(distance int, selAct selectionAction) { // split the distance information into constituent parts to be // used independently. words, direction := distance, 1 if distance < 0 { words, direction = distance*-1, -1 } // atEnd if caret is at either side of the buffer. caret := e.closestPosition(combinedPos{runes: e.caret.start}) atEnd := func() bool { return caret.ofs == 0 || caret.ofs == e.rr.len() } // next returns the appropriate rune given the direction. next := func() (r rune) { if direction < 0 { r, _ = e.rr.runeBefore(caret.ofs) } else { r, _ = e.rr.runeAt(caret.ofs) } return r } for ii := 0; ii < words; ii++ { for r := next(); unicode.IsSpace(r) && !atEnd(); r = next() { e.MoveCaret(direction, 0) caret = e.closestPosition(combinedPos{runes: e.caret.start}) } e.MoveCaret(direction, 0) caret = e.closestPosition(combinedPos{runes: e.caret.start}) for r := next(); !unicode.IsSpace(r) && !atEnd(); r = next() { e.MoveCaret(direction, 0) caret = e.closestPosition(combinedPos{runes: e.caret.start}) } } e.updateSelection(selAct) } // deleteWord deletes the next word(s) in the specified direction. // Unlike moveWord, deleteWord treats whitespace as a word itself. // Positive is forward, negative is backward. // Absolute values greater than one will delete that many words. // The selection counts as a single word. func (e *Editor) deleteWord(distance int) { if distance == 0 { return } if e.caret.start != e.caret.end { e.Delete(1) distance -= sign(distance) } if distance == 0 { return } // split the distance information into constituent parts to be // used independently. words, direction := distance, 1 if distance < 0 { words, direction = distance*-1, -1 } // atEnd if offset is at or beyond either side of the buffer. caret := e.closestPosition(combinedPos{runes: e.caret.start}) atEnd := func(offset int) bool { idx := caret.ofs + offset*direction return idx <= 0 || idx >= e.rr.len() } // next returns the appropriate rune and length given the direction and offset (in bytes). next := func(offset int) (r rune, l int) { idx := caret.ofs + offset*direction if idx < 0 { idx = 0 } else if idx > e.rr.len() { idx = e.rr.len() } if direction < 0 { r, l = e.rr.runeBefore(idx) } else { r, l = e.rr.runeAt(idx) } return } var runes = 1 _, bytes := e.rr.runeAt(caret.ofs) if direction < 0 { _, bytes = e.rr.runeBefore(caret.ofs) } for ii := 0; ii < words; ii++ { if r, _ := next(bytes); unicode.IsSpace(r) { for r, lg := next(bytes); unicode.IsSpace(r) && !atEnd(bytes); r, lg = next(bytes) { runes += 1 bytes += lg } } else { for r, lg := next(bytes); !unicode.IsSpace(r) && !atEnd(bytes); r, lg = next(bytes) { runes += 1 bytes += lg } } } e.Delete(runes * direction) } func (e *Editor) scrollToCaret() { caret := e.closestPosition(combinedPos{runes: e.caret.start}) l := e.lines[caret.lineCol.Y] if e.SingleLine { var dist int if d := caret.x.Floor() - e.scrollOff.X; d < 0 { dist = d } else if d := caret.x.Ceil() - (e.scrollOff.X + e.viewSize.X); d > 0 { dist = d } e.scrollRel(dist, 0) } else { miny := caret.y - l.Ascent.Ceil() maxy := caret.y + l.Descent.Ceil() var dist int if d := miny - e.scrollOff.Y; d < 0 { dist = d } else if d := maxy - (e.scrollOff.Y + e.viewSize.Y); d > 0 { dist = d } e.scrollRel(0, dist) } } // NumLines returns the number of lines in the editor. func (e *Editor) NumLines() int { e.makeValid() return len(e.lines) } // SelectionLen returns the length of the selection, in runes; it is // equivalent to utf8.RuneCountInString(e.SelectedText()). func (e *Editor) SelectionLen() int { return abs(e.caret.start - e.caret.end) } // Selection returns the start and end of the selection, as rune offsets. // start can be > end. func (e *Editor) Selection() (start, end int) { return e.caret.start, e.caret.end } // SetCaret moves the caret to start, and sets the selection end to end. start // and end are in runes, and represent offsets into the editor text. func (e *Editor) SetCaret(start, end int) { e.caret.start = e.closestPosition(combinedPos{runes: start}).runes e.caret.end = e.closestPosition(combinedPos{runes: end}).runes e.caret.scroll = true e.scroller.Stop() } // SelectedText returns the currently selected text (if any) from the editor. func (e *Editor) SelectedText() string { caretStart := e.closestPosition(combinedPos{runes: e.caret.start}) caretEnd := e.closestPosition(combinedPos{runes: e.caret.end}) start := min(caretStart.ofs, caretEnd.ofs) end := max(caretStart.ofs, caretEnd.ofs) buf := make([]byte, end-start) e.rr.Seek(int64(start), io.SeekStart) _, err := e.rr.Read(buf) if err != nil { // The only error that rr.Read can return is EOF, which just means no // selection, but we've already made sure that shouldn't happen. panic("impossible error because end is before e.rr.Len()") } return string(buf) } func (e *Editor) updateSelection(selAct selectionAction) { if selAct == selectionClear { e.ClearSelection() } } // ClearSelection clears the selection, by setting the selection end equal to // the selection start. func (e *Editor) ClearSelection() { e.caret.end = e.caret.start } // WriteTo implements io.WriterTo. func (e *Editor) WriteTo(w io.Writer) (int64, error) { return e.rr.WriteTo(w) } // Seek implements io.Seeker. func (e *Editor) Seek(offset int64, whence int) (int64, error) { return e.rr.Seek(0, io.SeekStart) } // Read implements io.Reader. func (e *Editor) Read(p []byte) (int, error) { return e.rr.Read(p) } func max(a, b int) int { if a > b { return a } return b } func min(a, b int) int { if a < b { return a } return b } func abs(n int) int { if n < 0 { return -n } return n } func sign(n int) int { switch { case n < 0: return -1 case n > 0: return 1 default: return 0 } } // sortPoints returns a and b sorted such that a2 <= b2. func sortPoints(a, b screenPos) (a2, b2 screenPos) { if b.Less(a) { return b, a } return a, b } func nullLayout(r io.Reader) ([]text.Line, error) { rr := bufio.NewReader(r) var rerr error var n int var buf bytes.Buffer for { r, _, err := rr.ReadRune() if err != nil { rerr = err break } n++ buf.WriteRune(r) } return []text.Line{ { Layout: text.Layout{ Text: buf.String(), Advances: make([]fixed.Int26_6, n), }, }, }, rerr } func (s ChangeEvent) isEditorEvent() {} func (s SubmitEvent) isEditorEvent() {} func (s SelectEvent) isEditorEvent() {}