Files
gio/ui/gesture/gestures.go
T
Elias Naur 32aae18293 ui,ui/app: convert Config to an interface
To keep the interface slim, remove the helper methods and shorten
the essential method, Pixels, to Px.

Add and use unexported Config implementation in the app package.

Signed-off-by: Elias Naur <mail@eliasnaur.com>
2019-07-10 17:20:55 +02:00

313 lines
5.7 KiB
Go

// SPDX-License-Identifier: Unlicense OR MIT
package gesture
import (
"math"
"runtime"
"time"
"gioui.org/ui"
"gioui.org/ui/f32"
"gioui.org/ui/input"
"gioui.org/ui/pointer"
)
type ClickEvent struct {
Type ClickType
Position f32.Point
Source pointer.Source
}
type ClickState uint8
type ClickType uint8
type Click struct {
State ClickState
}
type Scroll struct {
dragging bool
axis Axis
estimator estimator
flinger flinger
pid pointer.ID
grab bool
last int
// Leftover scroll.
scroll float32
}
type flinger struct {
// Current offset in pixels.
x float32
// Initial time.
t0 time.Time
// Initial velocity in pixels pr second.
v0 float32
}
type Axis uint8
const (
Horizontal Axis = iota
Vertical
)
const (
StateNormal ClickState = iota
StateFocused
StatePressed
)
const (
TypePress ClickType = iota
TypeClick
)
var (
touchSlop = ui.Dp(3)
// Pixels/second.
minFlingVelocity = ui.Dp(50)
maxFlingVelocity = ui.Dp(8000)
)
const (
thresholdVelocity = 1
)
func (c *Click) Add(ops *ui.Ops) {
op := pointer.HandlerOp{Key: c}
op.Add(ops)
}
func (c *Click) Next(q input.Events) (ClickEvent, bool) {
for {
evt, ok := q.Next(c)
if !ok {
break
}
e, ok := evt.(pointer.Event)
if !ok {
continue
}
switch e.Type {
case pointer.Release:
wasPressed := c.State == StatePressed
c.State = StateNormal
if wasPressed {
return ClickEvent{Type: TypeClick, Position: e.Position, Source: e.Source}, true
}
case pointer.Cancel:
c.State = StateNormal
case pointer.Press:
if c.State == StatePressed || !e.Hit {
break
}
c.State = StatePressed
return ClickEvent{Type: TypePress, Position: e.Position, Source: e.Source}, true
case pointer.Move:
if c.State == StatePressed && !e.Hit {
c.State = StateNormal
} else if c.State < StateFocused {
c.State = StateFocused
}
}
}
return ClickEvent{}, false
}
func (s *Scroll) Add(ops *ui.Ops) {
oph := pointer.HandlerOp{Key: s, Grab: s.grab}
oph.Add(ops)
if s.flinger.Active() {
ui.InvalidateOp{}.Add(ops)
}
}
func (s *Scroll) Stop() {
s.flinger = flinger{}
}
func (s *Scroll) Dragging() bool {
return s.dragging
}
func (s *Scroll) Scroll(cfg ui.Config, q input.Events, axis Axis) int {
if s.axis != axis {
s.axis = axis
return 0
}
total := 0
for {
evt, ok := q.Next(s)
if !ok {
break
}
e, ok := evt.(pointer.Event)
if !ok {
continue
}
switch e.Type {
case pointer.Press:
if s.dragging || e.Source != pointer.Touch {
break
}
s.Stop()
s.estimator = estimator{}
v := s.val(e.Position)
s.last = int(math.Round(float64(v)))
s.estimator.Sample(e.Time, v)
s.dragging = true
s.pid = e.PointerID
case pointer.Release:
if s.pid != e.PointerID {
break
}
fling := s.estimator.Estimate()
if slop, d := float32(cfg.Px(touchSlop)), fling.Distance; d >= slop || -slop >= d {
if min, v := float32(cfg.Px(minFlingVelocity)), fling.Velocity; v >= min || -min >= v {
max := float32(cfg.Px(maxFlingVelocity))
if v > max {
v = max
} else if v < -max {
v = -max
}
s.flinger.Init(cfg.Now(), v)
}
}
fallthrough
case pointer.Cancel:
s.dragging = false
s.grab = false
case pointer.Move:
// Scroll
switch s.axis {
case Horizontal:
s.scroll += e.Scroll.X
case Vertical:
s.scroll += e.Scroll.Y
}
iscroll := int(math.Round(float64(s.scroll)))
s.scroll -= float32(iscroll)
total += iscroll
if !s.dragging || s.pid != e.PointerID {
continue
}
// Drag
val := s.val(e.Position)
s.estimator.Sample(e.Time, val)
v := int(math.Round(float64(val)))
dist := s.last - v
if e.Priority < pointer.Grabbed {
slop := cfg.Px(touchSlop)
if dist := dist; dist >= slop || -slop >= dist {
s.grab = true
}
} else {
s.last = v
total += dist
}
}
}
total += s.flinger.Tick(cfg.Now())
return total
}
func (s *Scroll) val(p f32.Point) float32 {
if s.axis == Horizontal {
return p.X
} else {
return p.Y
}
}
func (s *Scroll) Active() bool {
return s.flinger.Active()
}
func (f *flinger) Init(now time.Time, v0 float32) {
f.t0 = now
f.v0 = v0
f.x = 0
}
func (f *flinger) Active() bool {
return f.v0 != 0
}
// Tick computes and returns a fling distance since
// the last time Tick was called.
func (f *flinger) Tick(now time.Time) int {
if !f.Active() {
return 0
}
var k float32
if runtime.GOOS == "darwin" {
k = -2 // iOS
} else {
k = -4.2 // Android and default
}
t := now.Sub(f.t0)
// The acceleration x''(t) of a point mass with a drag
// force, f, proportional with velocity, x'(t), is
// governed by the equation
//
// x''(t) = kx'(t)
//
// Given the starting position x(0) = 0, the starting
// velocity x'(0) = v0, the position is then
// given by
//
// x(t) = v0*e^(k*t)/k - v0/k
//
ekt := float32(math.Exp(float64(k) * t.Seconds()))
x := f.v0*ekt/k - f.v0/k
dist := x - f.x
idist := int(math.Round(float64(dist)))
f.x += float32(idist)
// Solving for the velocity x'(t) gives us
//
// x'(t) = v0*e^(k*t)
v := f.v0 * ekt
if v < thresholdVelocity && v > -thresholdVelocity {
f.v0 = 0
}
return idist
}
func (a Axis) String() string {
switch a {
case Horizontal:
return "Horizontal"
case Vertical:
return "Vertical"
default:
panic("invalid Axis")
}
}
func (ct ClickType) String() string {
switch ct {
case TypePress:
return "TypePress"
case TypeClick:
return "TypeClick"
default:
panic("invalid ClickType")
}
}
func (cs ClickState) String() string {
switch cs {
case StateNormal:
return "StateNormal"
case StateFocused:
return "StateFocused"
case StatePressed:
return "StatePressed"
default:
panic("invalid ClickState")
}
}