package tview import ( "bytes" "math" "regexp" "sync" "unicode/utf8" "github.com/gdamore/tcell" runewidth "github.com/mattn/go-runewidth" ) // textColors maps color strings which may be embedded in text sent to a // TextView to their tcell counterparts. var textColors = map[string]tcell.Color{ "red": tcell.ColorRed, "white": tcell.ColorWhite, "yellow": tcell.ColorYellow, "blue": tcell.ColorBlue, "green": tcell.ColorGreen, "cyan": tcell.ColorDarkCyan, "magenta": tcell.ColorDarkMagenta, } // Regular expressions commonly used throughout the TextView class. var ( colorPattern *regexp.Regexp // Initialized in the init() function. regionPattern = regexp.MustCompile(`\["([a-zA-Z0-9_,;: \-\.]*)"\]`) ) // textViewIndex contains information about each line displayed in the text // view. type textViewIndex struct { Line int // The index into the "buffer" variable. Pos int // The index into the "buffer" string. Color tcell.Color // The starting color. Region string // The starting region ID. } // TextView is a box which displays text. It implements the io.Writer interface // so you can stream text to it. This does not trigger a redraw automatically // but if a handler is installed via SetChangedFunc(), you can cause it to be // redrawn. // // Navigation // // If the text view is scrollable (the default), text is kept in a buffer which // may be larger than the screen and can be navigated similarly to Vim: // // - h, left arrow: Move left. // - l, right arrow: Move right. // - j, down arrow: Move down. // - k, up arrow: Move up. // - g, home: Move to the top. // - G, end: Move to the bottom. // - Ctrl-F, page down: Move down by one page. // - Ctrl-B, page up: Move up by one page. // // If the text is not scrollable, any text above the top visible line is // discarded. // // Navigation can be intercepted by installing a callback function via // SetCaptureFunc() which receives all keyboard events and decides which ones // to forward to the default handler. // // Colors // // If dynamic colors are enabled via SetDynamicColors(), text color can be // changed dynamically by embedding color strings in square brackets. For // example, // // This is a [red]warning[white]! // // will print the word "warning" in red. The following colors are currently // supported: white, yellow, blue, green, red, cyan, magenta. // // Regions and Highlights // // If regions are enabled via SetRegions(), you can define text regions within // the text and assign region IDs to them. Text regions start with region tags. // Region tags are square brackets that contain a region ID in double quotes, // for example: // // We define a ["rg"]region[""] here. // // A text region ends with the next region tag. Tags with no region ID ([""]) // don't start new regions. They can therefore be used to mark the end of a // region. Region IDs must satisfy the following regular expression: // // [a-zA-Z0-9_,;: \-\.]+ // // Regions can be highlighted by calling the Highlight() function with one or // more region IDs. This can be used to display search results, for example. // // The ScrollToHighlight() function can be used to jump to the currently // highlighted region once when the text view is drawn the next time. // // See https://github.com/rivo/tview/wiki/TextView for an example. type TextView struct { sync.Mutex *Box // The text buffer. buffer []string // The last bytes that have been received but are not part of the buffer yet. recentBytes []byte // The processed line index. This is nil if the buffer has changed and needs // to be re-indexed. index []*textViewIndex // Indices into the "index" slice which correspond to the first line of the // first highlight and the last line of the last highlight. This is calculated // during re-indexing. Set to -1 if there is no current highlight. fromHighlight, toHighlight int // A set of region IDs that are currently highlighted. highlights map[string]struct{} // The display width for which the index is created. indexWidth int // The width of the longest line in the index (not the buffer). longestLine int // The index of the first line shown in the text view. lineOffset int // If set to true, the text view will always remain at the end of the content. trackEnd bool // The number of characters to be skipped on each line (not in wrap mode). columnOffset int // The height of the content the last time the text view was drawn. pageSize int // If set to true, the text view will keep a buffer of text which can be // navigated when the text is longer than what fits into the box. scrollable bool // If set to true, lines that are longer than the available width are wrapped // onto the next line. If set to false, any characters beyond the available // width are discarded. wrap bool // The (starting) color of the text. textColor tcell.Color // If set to true, the text color can be changed dynamically by piping color // strings in square brackets to the text view. dynamicColors bool // If set to true, region tags can be used to define regions. regions bool // A temporary flag which, when true, will automatically bring the current // highlight(s) into the visible screen. scrollToHighlights bool // An optional function which will receive all key events sent to this text // view. Returning true also invokes the default key handling. capture func(*tcell.EventKey) bool // An optional function which is called when the content of the text view has // changed. changed func() // An optional function which is called when the user presses one of the // following keys: Escape, Enter, Tab, Backtab. done func(tcell.Key) } // NewTextView returns a new text view. func NewTextView() *TextView { return &TextView{ Box: NewBox(), highlights: make(map[string]struct{}), lineOffset: -1, scrollable: true, wrap: true, textColor: Styles.PrimaryTextColor, dynamicColors: false, } } // SetScrollable sets the flag that decides whether or not the text view is // scrollable. If true, text is kept in a buffer and can be navigated. func (t *TextView) SetScrollable(scrollable bool) *TextView { t.scrollable = scrollable if !scrollable { t.trackEnd = true } return t } // SetWrap sets the flag that, if true, leads to lines that are longer than the // available width being wrapped onto the next line. If false, any characters // beyond the available width are not displayed. func (t *TextView) SetWrap(wrap bool) *TextView { if t.wrap != wrap { t.index = nil } t.wrap = wrap return t } // SetTextColor sets the initial color of the text (which can be changed // dynamically by sending color strings in square brackets to the text view if // dynamic colors are enabled). func (t *TextView) SetTextColor(color tcell.Color) *TextView { t.textColor = color return t } // SetDynamicColors sets the flag that allows the text color to be changed // dynamically. See class description for details. func (t *TextView) SetDynamicColors(dynamic bool) *TextView { if t.dynamicColors != dynamic { t.index = nil } t.dynamicColors = dynamic return t } // SetRegions sets the flag that allows to define regions in the text. See class // description for details. func (t *TextView) SetRegions(regions bool) *TextView { t.regions = regions return t } // SetCaptureFunc sets a handler which is called whenever a key is pressed. // This allows you to override the default key handling of the text view. // Returning true will allow the default key handling to go forward after the // handler returns. Returning false will disable any default key handling. func (t *TextView) SetCaptureFunc(handler func(event *tcell.EventKey) bool) *TextView { t.capture = handler return t } // SetChangedFunc sets a handler function which is called when the text of the // text view has changed. This is typically used to cause the application to // redraw the screen. func (t *TextView) SetChangedFunc(handler func()) *TextView { t.changed = handler return t } // SetDoneFunc sets a handler which is called when the user presses on the // following keys: Escape, Enter, Tab, Backtab. The key is passed to the // handler. func (t *TextView) SetDoneFunc(handler func(key tcell.Key)) *TextView { t.done = handler return t } // Clear removes all text from the buffer. func (t *TextView) Clear() *TextView { t.buffer = nil t.recentBytes = nil t.index = nil return t } // Highlight specifies which regions should be highlighted. See class // description for details on regions. Empty region strings are ignored. // // Text in highlighted regions will be drawn inverted, i.e. with their // background and foreground colors swapped. // // Calling this function will remove any previous highlights. To remove all // highlights, call this function without any arguments. func (t *TextView) Highlight(regionIDs ...string) *TextView { t.highlights = make(map[string]struct{}) for _, id := range regionIDs { if id == "" { continue } t.highlights[id] = struct{}{} } return t } // GetHighlights returns the IDs of all currently highlighted regions. func (t *TextView) GetHighlights() (regionIDs []string) { for id := range t.highlights { regionIDs = append(regionIDs, id) } return } // ScrollToHighlight will cause the visible area to be scrolled so that the // highlighted regions appear in the visible area of the text view. This // repositioning happens the next time the text view is drawn. It happens only // once so you will need to call this function repeatedly to always keep // highlighted regions in view. // // Nothing happens if there are no highlighted regions or if the text view is // not scrollable. func (t *TextView) ScrollToHighlight() *TextView { if len(t.highlights) == 0 || !t.scrollable || !t.regions { return t } t.index = nil t.scrollToHighlights = true t.trackEnd = false return t } // GetRegionText returns the text of the region with the given ID. If dynamic // colors are enabled, color tags are stripped from the text. Newlines are // always returned as '\n' runes. // // If the region does not exist or if regions are turned off, an empty string // is returned. func (t *TextView) GetRegionText(regionID string) string { if !t.regions || regionID == "" { return "" } var ( buffer bytes.Buffer currentRegionID string ) for _, str := range t.buffer { // Find all color tags in this line. var colorTagIndices [][]int if t.dynamicColors { colorTagIndices = colorPattern.FindAllStringIndex(str, -1) } // Find all regions in this line. var ( regionIndices [][]int regions [][]string ) if t.regions { regionIndices = regionPattern.FindAllStringIndex(str, -1) regions = regionPattern.FindAllStringSubmatch(str, -1) } // Analyze this line. var currentTag, currentRegion int for pos, ch := range str { // Skip any color tags. if currentTag < len(colorTagIndices) && pos >= colorTagIndices[currentTag][0] && pos < colorTagIndices[currentTag][1] { if pos == colorTagIndices[currentTag][1]-1 { currentTag++ } continue } // Skip any regions. if currentRegion < len(regionIndices) && pos >= regionIndices[currentRegion][0] && pos < regionIndices[currentRegion][1] { if pos == regionIndices[currentRegion][1]-1 { if currentRegionID == regionID { // This is the end of the requested region. We're done. return buffer.String() } currentRegionID = regions[currentRegion][1] currentRegion++ } continue } // Add this rune. if currentRegionID == regionID { buffer.WriteRune(ch) } } // Add newline. if currentRegionID == regionID { buffer.WriteRune('\n') } } return buffer.String() } // Write lets us implement the io.Writer interface. func (t *TextView) Write(p []byte) (n int, err error) { // Notify at the end. if t.changed != nil { defer t.changed() } t.Lock() defer t.Unlock() // Copy data over. newBytes := append(t.recentBytes, p...) t.recentBytes = nil // If we have a trailing invalid UTF-8 byte, we'll wait. if r, _ := utf8.DecodeLastRune(p); r == utf8.RuneError { t.recentBytes = newBytes return len(p), nil } // If we have a trailing open dynamic color, exclude it. if t.dynamicColors { openColor := regexp.MustCompile(`\[[a-z]+$`) location := openColor.FindIndex(newBytes) if location != nil { t.recentBytes = newBytes[location[0]:] newBytes = newBytes[:location[0]] } } // Transform the new bytes into strings. newLine := regexp.MustCompile(`\r?\n`) for index, line := range newLine.Split(string(newBytes), -1) { if index == 0 { if len(t.buffer) == 0 { t.buffer = []string{line} } else { t.buffer[len(t.buffer)-1] += line } } else { t.buffer = append(t.buffer, line) } } // Reset the index. t.index = nil return len(p), nil } // reindexBuffer re-indexes the buffer such that we can use it to easily draw // the buffer onto the screen. Each line in the index will contain a pointer // into the buffer from which on we will print text. It will also contain the // color with which the line starts. func (t *TextView) reindexBuffer(width int) { if t.index != nil && width == t.indexWidth { return // Nothing has changed. We can still use the current index. } t.index = nil t.fromHighlight, t.toHighlight = -1, -1 var ( regionID string highlighted bool ) t.longestLine = 0 color := t.textColor if !t.wrap { width = math.MaxInt32 } for index, str := range t.buffer { // Find all color tags in this line. var ( colorTagIndices [][]int colorTags [][]string ) if t.dynamicColors { colorTagIndices = colorPattern.FindAllStringIndex(str, -1) colorTags = colorPattern.FindAllStringSubmatch(str, -1) } // Find all regions in this line. var ( regionIndices [][]int regions [][]string ) if t.regions { regionIndices = regionPattern.FindAllStringIndex(str, -1) regions = regionPattern.FindAllStringSubmatch(str, -1) } // We also keep a reference to empty lines. if len(str) == 0 { t.index = append(t.index, &textViewIndex{ Line: index, Pos: 0, Color: color, Region: regionID, }) } // Break down the line. var currentTag, currentRegion, currentWidth int for pos, ch := range str { // Skip any color tags. if currentTag < len(colorTags) && pos >= colorTagIndices[currentTag][0] && pos < colorTagIndices[currentTag][1] { if pos == colorTagIndices[currentTag][1]-1 { color = textColors[colorTags[currentTag][1]] currentTag++ } continue } // Check regions. if currentRegion < len(regionIndices) && pos >= regionIndices[currentRegion][0] && pos < regionIndices[currentRegion][1] { if pos == regionIndices[currentRegion][1]-1 { // We're done with this region. regionID = regions[currentRegion][1] // Is this region highlighted? _, highlighted = t.highlights[regionID] currentRegion++ } continue } // Add this line. if currentWidth == 0 { t.index = append(t.index, &textViewIndex{ Line: index, Pos: pos, Color: color, Region: regionID, }) } // Update highlight range. if highlighted { line := len(t.index) - 1 if t.fromHighlight < 0 { t.fromHighlight, t.toHighlight = line, line } else if line > t.toHighlight { t.toHighlight = line } } // Proceed. currentWidth += runewidth.RuneWidth(ch) // Have we crossed the width? if t.wrap && currentWidth >= width { currentWidth = 0 } // Do we have a new maximum width? if currentWidth > t.longestLine { t.longestLine = currentWidth } } } t.indexWidth = width } // Draw draws this primitive onto the screen. func (t *TextView) Draw(screen tcell.Screen) { t.Lock() defer t.Unlock() t.Box.Draw(screen) // Get the available size. x, y, width, height := t.GetInnerRect() t.pageSize = height // Re-index. t.reindexBuffer(width) // Move to highlighted regions. if t.regions && t.scrollToHighlights && t.fromHighlight >= 0 { // Do we fit the entire height? if t.toHighlight-t.fromHighlight+1 < height { // Yes, let's center the highlights. t.lineOffset = (t.fromHighlight + t.toHighlight - height) / 2 } else { // No, let's move to the start of the highlights. t.lineOffset = t.fromHighlight } } t.scrollToHighlights = false // Adjust line offset. if t.lineOffset+height > len(t.index) { t.trackEnd = true } if t.trackEnd { t.lineOffset = len(t.index) - height } if t.lineOffset < 0 { t.lineOffset = 0 } // Adjust column offset. if t.columnOffset+width > t.longestLine { t.columnOffset = t.longestLine - width } if t.columnOffset < 0 { t.columnOffset = 0 } // Draw the buffer. for line := t.lineOffset; line < len(t.index); line++ { // Are we done? if line-t.lineOffset >= height { break } // Get the text for this line. index := t.index[line] text := t.buffer[index.Line][index.Pos:] color := index.Color regionID := index.Region // Get color tags. var ( colorTagIndices [][]int colorTags [][]string ) if t.dynamicColors { colorTagIndices = colorPattern.FindAllStringIndex(text, -1) colorTags = colorPattern.FindAllStringSubmatch(text, -1) } // Get regions. var ( regionIndices [][]int regions [][]string ) if t.regions { regionIndices = regionPattern.FindAllStringIndex(text, -1) regions = regionPattern.FindAllStringSubmatch(text, -1) } // Print one line. var currentTag, currentRegion, skip, posX int for pos, ch := range text { // Get the color. if currentTag < len(colorTags) && pos >= colorTagIndices[currentTag][0] && pos < colorTagIndices[currentTag][1] { if pos == colorTagIndices[currentTag][1]-1 { color = textColors[colorTags[currentTag][1]] currentTag++ } continue } // Get the region. if currentRegion < len(regionIndices) && pos >= regionIndices[currentRegion][0] && pos < regionIndices[currentRegion][1] { if pos == regionIndices[currentRegion][1]-1 { regionID = regions[currentRegion][1] currentRegion++ } continue } // Skip to the right. if !t.wrap && skip < t.columnOffset { skip++ continue } // Stop at the right border. chWidth := runewidth.RuneWidth(ch) if posX+chWidth > width { break } // Do we highlight this character? style := tcell.StyleDefault.Background(t.backgroundColor).Foreground(color) if len(regionID) > 0 { if _, ok := t.highlights[regionID]; ok { style = tcell.StyleDefault.Background(color).Foreground(t.backgroundColor) } } // Draw the character. for offset := 0; offset < chWidth; offset++ { screen.SetContent(x+posX+offset, y+line-t.lineOffset, ch, nil, style) } // Advance. posX += chWidth } } // If this view is not scrollable, we'll purge the buffer of lines that have // scrolled out of view. if !t.scrollable && t.lineOffset > 0 { t.buffer = t.buffer[t.index[t.lineOffset].Line:] t.index = nil } } // InputHandler returns the handler for this primitive. func (t *TextView) InputHandler() func(event *tcell.EventKey, setFocus func(p Primitive)) { return func(event *tcell.EventKey, setFocus func(p Primitive)) { // Do we pass this event on? if t.capture != nil { if !t.capture(event) { return } } key := event.Key() if key == tcell.KeyEscape || key == tcell.KeyEnter || key == tcell.KeyTab || key == tcell.KeyBacktab { if t.done != nil { t.done(key) } return } if !t.scrollable { return } switch key { case tcell.KeyRune: switch event.Rune() { case 'g': // Home. t.trackEnd = false t.lineOffset = 0 t.columnOffset = 0 case 'G': // End. t.trackEnd = true t.columnOffset = 0 case 'j': // Down. t.lineOffset++ case 'k': // Up. t.trackEnd = false t.lineOffset-- case 'h': // Left. t.columnOffset-- case 'l': // Right. t.columnOffset++ } case tcell.KeyHome: t.trackEnd = false t.lineOffset = 0 t.columnOffset = 0 case tcell.KeyEnd: t.trackEnd = true t.columnOffset = 0 case tcell.KeyUp: t.trackEnd = false t.lineOffset-- case tcell.KeyDown: t.lineOffset++ case tcell.KeyLeft: t.columnOffset-- case tcell.KeyRight: t.columnOffset++ case tcell.KeyPgDn, tcell.KeyCtrlF: t.lineOffset += t.pageSize case tcell.KeyPgUp, tcell.KeyCtrlB: t.trackEnd = false t.lineOffset -= t.pageSize } } }