Files
gio/widget/label.go
T
Elias Naur 936c266b03 all: [API] split operation stack into per-state stacks
The op.Save and Load methods exist to support the need for
transformation, clip, pointer area state to behave as stacks. For
example, layout needs to apply an offset to its children but not
subsequent operations.

Before this change, op.Save and Load were used to save and restore the
state:

    ops := new(op.Ops)
    // Save state.
    state := op.Save(ops)
    // Apply offset.
    op.Offset(...).Add(ops)
    // Draw with offset applied.
    draw(ops)
    // Restore state.
    state.Load()

A drawback with the op.Save mechanism is that there is no direct
connection between the state change and the saving and loading of state.
This causes confusion as to when a Save/Load is needed and who is
responsible for performing them, which leads to subtle bugs and over-use
of Save/Loads.

This change gets rid of the general state stack and replaces it with
per-state stacks. There is now a stack for transformation, clip, pointer
areas, and they can only be restored by the code pushing state to them.
The example above now becomes:

    ops := new(op.Ops)
    // Push offset to the transformation stack.
    stack := op.Offset(...).Push(ops)
    // Draw with offset applied.
    draw(ops)
    // Restore state.
    stack.Pop()

For convenience, transformation also be Add'ed if the stack operation is
not required.

Simple state such as the current material no longer has a way to be
restored; it is assumed the client of a PaintOp adds their desired
material operation before it.

API change: replace op.Save/Load with explicit Push/Pop scopes for
op.TransformOps, pointer.AreaOps, clip.Ops.

To ease porting, this change retains a version of op.Save/Load that
saves and restores the transformation and clip stacks. It also retains
an Add method for clip.Op.

Signed-off-by: Elias Naur <mail@eliasnaur.com>
2021-10-08 17:21:56 +02:00

250 lines
6.0 KiB
Go

// SPDX-License-Identifier: Unlicense OR MIT
package widget
import (
"fmt"
"image"
"unicode/utf8"
"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"
)
// Label is a widget for laying out and drawing text.
type Label struct {
// Alignment specify the text alignment.
Alignment text.Alignment
// MaxLines limits the number of lines. Zero means no limit.
MaxLines int
}
// screenPos describes a character position (in text line and column numbers,
// not pixels): Y = line number, X = rune column.
type screenPos image.Point
type segmentIterator struct {
Lines []text.Line
Clip image.Rectangle
Alignment text.Alignment
Width int
Offset image.Point
startSel screenPos
endSel screenPos
pos screenPos // current position
line text.Line // current line
layout text.Layout // current line's Layout
// pixel positions
off fixed.Point26_6
y, prevDesc fixed.Int26_6
}
const inf = 1e6
func (l *segmentIterator) Next() (text.Layout, image.Point, bool, int, image.Point, bool) {
for l.pos.Y < len(l.Lines) {
if l.pos.X == 0 {
l.line = l.Lines[l.pos.Y]
// Calculate X & Y pixel coordinates of left edge of line. We need y
// for the next line, so it's in l, but we only need x here, so it's
// not.
x := align(l.Alignment, l.line.Width, l.Width) + fixed.I(l.Offset.X)
l.y += l.prevDesc + l.line.Ascent
l.prevDesc = l.line.Descent
// Align baseline and line start to the pixel grid.
l.off = fixed.Point26_6{X: fixed.I(x.Floor()), Y: fixed.I(l.y.Ceil())}
l.y = l.off.Y
l.off.Y += fixed.I(l.Offset.Y)
if (l.off.Y + l.line.Bounds.Min.Y).Floor() > l.Clip.Max.Y {
break
}
if (l.off.Y + l.line.Bounds.Max.Y).Ceil() < l.Clip.Min.Y {
// This line is outside/before the clip area; go on to the next line.
l.pos.Y++
continue
}
// Copy the line's Layout, since we slice it up later.
l.layout = l.line.Layout
// Find the left edge of the text visible in the l.Clip clipping
// area.
for len(l.layout.Advances) > 0 {
_, n := utf8.DecodeRuneInString(l.layout.Text)
adv := l.layout.Advances[0]
if (l.off.X + adv + l.line.Bounds.Max.X - l.line.Width).Ceil() >= l.Clip.Min.X {
break
}
l.off.X += adv
l.layout.Text = l.layout.Text[n:]
l.layout.Advances = l.layout.Advances[1:]
l.pos.X++
}
}
selected := l.inSelection()
endx := l.off.X
rune := 0
nextLine := true
retLayout := l.layout
for n := range l.layout.Text {
selChanged := selected != l.inSelection()
beyondClipEdge := (endx + l.line.Bounds.Min.X).Floor() > l.Clip.Max.X
if selChanged || beyondClipEdge {
retLayout.Advances = l.layout.Advances[:rune]
retLayout.Text = l.layout.Text[:n]
if selChanged {
// Save the rest of the line
l.layout.Advances = l.layout.Advances[rune:]
l.layout.Text = l.layout.Text[n:]
nextLine = false
}
break
}
endx += l.layout.Advances[rune]
rune++
l.pos.X++
}
offFloor := image.Point{X: l.off.X.Floor(), Y: l.off.Y.Floor()}
// Calculate the width & height if the returned text.
//
// If there's a better way to do this, I'm all ears.
var d fixed.Int26_6
for _, adv := range retLayout.Advances {
d += adv
}
size := image.Point{
X: d.Ceil(),
Y: (l.line.Ascent + l.line.Descent).Ceil(),
}
if nextLine {
l.pos.Y++
l.pos.X = 0
} else {
l.off.X = endx
}
return retLayout, offFloor, selected, l.prevDesc.Ceil() - size.Y, size, true
}
return text.Layout{}, image.Point{}, false, 0, image.Point{}, false
}
func (l *segmentIterator) inSelection() bool {
return l.startSel.LessOrEqual(l.pos) &&
l.pos.Less(l.endSel)
}
func (p1 screenPos) LessOrEqual(p2 screenPos) bool {
return p1.Y < p2.Y || (p1.Y == p2.Y && p1.X <= p2.X)
}
func (p1 screenPos) Less(p2 screenPos) bool {
return p1.Y < p2.Y || (p1.Y == p2.Y && p1.X < p2.X)
}
func (l Label) Layout(gtx layout.Context, s text.Shaper, font text.Font, size unit.Value, txt string) layout.Dimensions {
cs := gtx.Constraints
textSize := fixed.I(gtx.Px(size))
lines := s.LayoutString(font, textSize, cs.Max.X, txt)
if max := l.MaxLines; max > 0 && len(lines) > max {
lines = lines[:max]
}
dims := linesDimens(lines)
dims.Size = cs.Constrain(dims.Size)
cl := textPadding(lines)
cl.Max = cl.Max.Add(dims.Size)
it := segmentIterator{
Lines: lines,
Clip: cl,
Alignment: l.Alignment,
Width: dims.Size.X,
}
for {
l, off, _, _, _, ok := it.Next()
if !ok {
break
}
t := op.Offset(layout.FPt(off)).Push(gtx.Ops)
rcl := clip.Rect(cl.Sub(off)).Push(gtx.Ops)
cl := s.Shape(font, textSize, l).Push(gtx.Ops)
paint.PaintOp{}.Add(gtx.Ops)
cl.Pop()
rcl.Pop()
t.Pop()
}
return dims
}
func textPadding(lines []text.Line) (padding image.Rectangle) {
if len(lines) == 0 {
return
}
first := lines[0]
if d := first.Ascent + first.Bounds.Min.Y; d < 0 {
padding.Min.Y = d.Ceil()
}
last := lines[len(lines)-1]
if d := last.Bounds.Max.Y - last.Descent; d > 0 {
padding.Max.Y = d.Ceil()
}
if d := first.Bounds.Min.X; d < 0 {
padding.Min.X = d.Ceil()
}
if d := first.Bounds.Max.X - first.Width; d > 0 {
padding.Max.X = d.Ceil()
}
return
}
func linesDimens(lines []text.Line) layout.Dimensions {
var width fixed.Int26_6
var h int
var baseline int
if len(lines) > 0 {
baseline = lines[0].Ascent.Ceil()
var prevDesc fixed.Int26_6
for _, l := range lines {
h += (prevDesc + l.Ascent).Ceil()
prevDesc = l.Descent
if l.Width > width {
width = l.Width
}
}
h += lines[len(lines)-1].Descent.Ceil()
}
w := width.Ceil()
return layout.Dimensions{
Size: image.Point{
X: w,
Y: h,
},
Baseline: h - baseline,
}
}
func align(align text.Alignment, width fixed.Int26_6, maxWidth int) fixed.Int26_6 {
mw := fixed.I(maxWidth)
switch align {
case text.Middle:
return fixed.I(((mw - width) / 2).Floor())
case text.End:
return fixed.I((mw - width).Floor())
case text.Start:
return 0
default:
panic(fmt.Errorf("unknown alignment %v", align))
}
}