shiny/example/fluid/main.go - exp - Git at Google

 // Copyright 2016 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 //go:build example
 // +build example

 //
 // This build tag means that "go install golang.org/x/exp/shiny/..." doesn't
 // install this example program. Use "go run main.go" to run it or "go install
 // -tags=example" to install it.

 // Fluid is a fluid dynamics simulator. It is based on Jos Stam, "Real-Time
 // Fluid Dynamics for Games", Proceedings of the Game Developer Conference,
 // March 2003. See
 // http://www.dgp.toronto.edu/people/stam/reality/Research/pub.html
 package main

 import (
 	"image"
 	"image/color"
 	"image/draw"
 	"log"
 	"sync"
 	"time"

 	"golang.org/x/exp/shiny/driver"
 	"golang.org/x/exp/shiny/screen"
 	"golang.org/x/mobile/event/lifecycle"
 	"golang.org/x/mobile/event/mouse"
 	"golang.org/x/mobile/event/paint"
 	"golang.org/x/mobile/event/size"
 )

 const (
 	N = 128 // The grid of cells has size NxN.

 	tickDuration = time.Second / 60

 	// These remaining numbers have magic values, determined by trial and error
 	// to look good, rather than being derived from first principles.
 	iterations = 20
 	dt         = 0.1
 	diff       = 0
 	visc       = 0
 	force      = 5
 	source     = 20
 	fade       = 0.89
 )

 func main() {
 	driver.Main(func(s screen.Screen) {
 		w, err := s.NewWindow(&screen.NewWindowOptions{
 			Title: "Fluid Shiny Example",
 		})
 		if err != nil {
 			log.Fatal(err)
 		}
 		buf, tex := screen.Buffer(nil), screen.Texture(nil)
 		defer func() {
 			if buf != nil {
 				tex.Release()
 				buf.Release()
 			}
 			w.Release()
 		}()

 		go simulate(w)

 		var (
 			buttonDown bool
 			sz         size.Event
 		)
 		for {
 			publish := false

 			switch e := w.NextEvent().(type) {
 			case lifecycle.Event:
 				if e.To == lifecycle.StageDead {
 					return
 				}

 				switch e.Crosses(lifecycle.StageVisible) {
 				case lifecycle.CrossOn:
 					pauseChan <- play
 					var err error
 					buf, err = s.NewBuffer(image.Point{N, N})
 					if err != nil {
 						log.Fatal(err)
 					}
 					tex, err = s.NewTexture(image.Point{N, N})
 					if err != nil {
 						log.Fatal(err)
 					}
 					tex.Fill(tex.Bounds(), color.White, draw.Src)

 				case lifecycle.CrossOff:
 					pauseChan <- pause
 					tex.Release()
 					tex = nil
 					buf.Release()
 					buf = nil
 				}

 			case mouse.Event:
 				if e.Button == mouse.ButtonLeft {
 					buttonDown = e.Direction == mouse.DirPress
 				}
 				if !buttonDown {
 					break
 				}
 				z := sz.Size()
 				x := int(e.X) * N / z.X
 				y := int(e.Y) * N / z.Y
 				if x < 0 || N <= x || y < 0 || N <= y {
 					break
 				}

 				shared.mu.Lock()
 				shared.mouseEvents = append(shared.mouseEvents, image.Point{x, y})
 				shared.mu.Unlock()

 			case paint.Event:
 				publish = buf != nil

 			case size.Event:
 				sz = e

 			case uploadEvent:
 				shared.mu.Lock()
 				if buf != nil {
 					copy(buf.RGBA().Pix, shared.pix)
 					publish = true
 				}
 				shared.uploadEventSent = false
 				shared.mu.Unlock()

 				if publish {
 					tex.Upload(image.Point{}, buf, buf.Bounds())
 				}

 			case error:
 				log.Print(e)
 			}

 			if publish {
 				w.Scale(sz.Bounds(), tex, tex.Bounds(), draw.Src, nil)
 				w.Publish()
 			}
 		}
 	})
 }

 const (
 	pause = false
 	play  = true
 )

 // pauseChan lets the UI event goroutine pause and play the CPU-intensive
 // simulation goroutine depending on whether the window is visible (e.g.
 // minimized). 64 should be large enough, in typical use, so that the former
 // doesn't ever block on the latter.
 var pauseChan = make(chan bool, 64)

 // uploadEvent signals that the shared pix slice should be uploaded to the
 // screen.Texture via the screen.Buffer.
 type uploadEvent struct{}

 var shared = struct {
 	mu              sync.Mutex
 	uploadEventSent bool
 	mouseEvents     []image.Point
 	pix             []byte
 }{
 	pix: make([]byte, 4*N*N),
 }

 func simulate(q screen.EventDeque) {
 	var (
 		dens, densPrev array
 		u, uPrev       array
 		v, vPrev       array
 		xPrev, yPrev   int
 		havePrevLoc    bool
 	)

 	ticker := time.NewTicker(tickDuration)
 	var tickerC <-chan time.Time
 	for {
 		select {
 		case p := <-pauseChan:
 			if p == pause {
 				tickerC = nil
 			} else {
 				tickerC = ticker.C
 			}
 			continue
 		case <-tickerC:
 		}

 		shared.mu.Lock()
 		for _, p := range shared.mouseEvents {
 			dens[p.X+1][p.Y] = source
 			if havePrevLoc {
 				u[p.X+1][p.Y+1] = force * float32(p.X-xPrev)
 				v[p.X+1][p.Y+1] = force * float32(p.Y-yPrev)
 			}
 			xPrev, yPrev, havePrevLoc = p.X, p.Y, true
 		}
 		shared.mouseEvents = shared.mouseEvents[:0]
 		shared.mu.Unlock()

 		velStep(&u, &v, &uPrev, &vPrev)
 		densStep(&dens, &densPrev, &u, &v)

 		// This fade isn't part of Stam's GDC03 paper, but it looks nice.
 		for i := range dens {
 			for j := range dens[i] {
 				dens[i][j] *= fade
 			}
 		}

 		shared.mu.Lock()
 		for y := 0; y < N; y++ {
 			for x := 0; x < N; x++ {
 				d := int32(dens[x+1][y+1] * 0xff)
 				if d < 0 {
 					d = 0
 				} else if d > 0xff {
 					d = 0xff
 				}
 				v := 255 - uint8(d)
 				p := (N*y + x) * 4
 				shared.pix[p+0] = v
 				shared.pix[p+1] = v
 				shared.pix[p+2] = v
 				shared.pix[p+3] = 0xff
 			}
 		}
 		uploadEventSent := shared.uploadEventSent
 		shared.uploadEventSent = true
 		shared.mu.Unlock()

 		if !uploadEventSent {
 			q.Send(uploadEvent{})
 		}
 	}
 }

 // All of the remaining code more or less comes from Stam's GDC03 paper.

 type array [N + 2][N + 2]float32

 func addSource(x, s *array) {
 	for i := range x {
 		for j := range x[i] {
 			x[i][j] += dt * s[i][j]
 		}
 	}
 }

 func setBnd(b int, x *array) {
 	switch b {
 	case 0:
 		for i := 1; i <= N; i++ {
 			x[0+0][i] = +x[1][i]
 			x[N+1][i] = +x[N][i]
 			x[i][0+0] = +x[i][1]
 			x[i][N+1] = +x[i][N]
 		}
 	case 1:
 		for i := 1; i <= N; i++ {
 			x[0+0][i] = -x[1][i]
 			x[N+1][i] = -x[N][i]
 			x[i][0+0] = +x[i][1]
 			x[i][N+1] = +x[i][N]
 		}
 	case 2:
 		for i := 1; i <= N; i++ {
 			x[0+0][i] = +x[1][i]
 			x[N+1][i] = +x[N][i]
 			x[i][0+0] = -x[i][1]
 			x[i][N+1] = -x[i][N]
 		}
 	}
 	x[0+0][0+0] = 0.5 * (x[1][0+0] + x[0+0][1])
 	x[0+0][N+1] = 0.5 * (x[1][N+1] + x[0+0][N])
 	x[N+1][0+0] = 0.5 * (x[N][0+0] + x[N+1][1])
 	x[N+1][N+1] = 0.5 * (x[N][N+1] + x[N+1][N])
 }

 func linSolve(b int, x, x0 *array, a, c float32) {
 	// This if block isn't part of Stam's GDC03 paper, but it's a nice
 	// optimization when the diff diffusion parameter is zero.
 	if a == 0 && c == 1 {
 		for i := 1; i <= N; i++ {
 			for j := 1; j <= N; j++ {
 				x[i][j] = x0[i][j]
 			}
 		}
 		setBnd(b, x)
 		return
 	}

 	invC := 1 / c
 	for k := 0; k < iterations; k++ {
 		for i := 1; i <= N; i++ {
 			for j := 1; j <= N; j++ {
 				x[i][j] = (x0[i][j] + a*(x[i-1][j]+x[i+1][j]+x[i][j-1]+x[i][j+1])) * invC
 			}
 		}
 		setBnd(b, x)
 	}
 }

 func diffuse(b int, x, x0 *array, diff float32) {
 	a := dt * diff * N * N
 	linSolve(b, x, x0, a, 1+4*a)
 }

 func advect(b int, d, d0, u, v *array) {
 	const dt0 = dt * N
 	for i := 1; i <= N; i++ {
 		for j := 1; j <= N; j++ {
 			x := float32(i) - dt0*u[i][j]
 			if x < 0.5 {
 				x = 0.5
 			}
 			if x > N+0.5 {
 				x = N + 0.5
 			}
 			i0 := int(x)
 			i1 := i0 + 1

 			y := float32(j) - dt0*v[i][j]
 			if y < 0.5 {
 				y = 0.5
 			}
 			if y > N+0.5 {
 				y = N + 0.5
 			}
 			j0 := int(y)
 			j1 := j0 + 1

 			s1 := x - float32(i0)
 			s0 := 1 - s1
 			t1 := y - float32(j0)
 			t0 := 1 - t1
 			d[i][j] = s0*(t0*d0[i0][j0]+t1*d0[i0][j1]) + s1*(t0*d0[i1][j0]+t1*d0[i1][j1])
 		}
 	}
 	setBnd(b, d)
 }

 func project(u, v, p, div *array) {
 	for i := 1; i <= N; i++ {
 		for j := 1; j <= N; j++ {
 			div[i][j] = (u[i+1][j] - u[i-1][j] + v[i][j+1] - v[i][j-1]) / (-2 * N)
 			p[i][j] = 0
 		}
 	}
 	setBnd(0, div)
 	setBnd(0, p)
 	linSolve(0, p, div, 1, 4)
 	for i := 1; i <= N; i++ {
 		for j := 1; j <= N; j++ {
 			u[i][j] -= (N / 2) * (p[i+1][j+0] - p[i-1][j+0])
 			v[i][j] -= (N / 2) * (p[i+0][j+1] - p[i+0][j-1])
 		}
 	}
 	setBnd(1, u)
 	setBnd(2, v)
 }

 func velStep(u, v, u0, v0 *array) {
 	addSource(u, u0)
 	addSource(v, v0)
 	u0, u = u, u0
 	diffuse(1, u, u0, visc)
 	v0, v = v, v0
 	diffuse(2, v, v0, visc)
 	project(u, v, u0, v0)
 	u0, u = u, u0
 	v0, v = v, v0
 	advect(1, u, u0, u0, v0)
 	advect(2, v, v0, u0, v0)
 	project(u, v, u0, v0)
 }

 func densStep(x, x0, u, v *array) {
 	addSource(x, x0)
 	x0, x = x, x0
 	diffuse(0, x, x0, diff)
 	x0, x = x, x0
 	advect(0, x, x0, u, v)
 }
	// Copyright 2016 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	//go:build example
	// +build example

	//
	// This build tag means that "go install golang.org/x/exp/shiny/..." doesn't
	// install this example program. Use "go run main.go" to run it or "go install
	// -tags=example" to install it.

	// Fluid is a fluid dynamics simulator. It is based on Jos Stam, "Real-Time
	// Fluid Dynamics for Games", Proceedings of the Game Developer Conference,
	// March 2003. See
	// http://www.dgp.toronto.edu/people/stam/reality/Research/pub.html
	package main

	import (
	"image"
	"image/color"
	"image/draw"
	"log"
	"sync"
	"time"

	"golang.org/x/exp/shiny/driver"
	"golang.org/x/exp/shiny/screen"
	"golang.org/x/mobile/event/lifecycle"
	"golang.org/x/mobile/event/mouse"
	"golang.org/x/mobile/event/paint"
	"golang.org/x/mobile/event/size"
	)

	const (
	N = 128 // The grid of cells has size NxN.

	tickDuration = time.Second / 60

	// These remaining numbers have magic values, determined by trial and error
	// to look good, rather than being derived from first principles.
	iterations = 20
	dt = 0.1
	diff = 0
	visc = 0
	force = 5
	source = 20
	fade = 0.89
	)

	func main() {
	driver.Main(func(s screen.Screen) {
	w, err := s.NewWindow(&screen.NewWindowOptions{
	Title: "Fluid Shiny Example",
	})
	if err != nil {
	log.Fatal(err)
	}
	buf, tex := screen.Buffer(nil), screen.Texture(nil)
	defer func() {
	if buf != nil {
	tex.Release()
	buf.Release()
	}
	w.Release()
	}()

	go simulate(w)

	var (
	buttonDown bool
	sz size.Event
	)
	for {
	publish := false

	switch e := w.NextEvent().(type) {
	case lifecycle.Event:
	if e.To == lifecycle.StageDead {
	return
	}

	switch e.Crosses(lifecycle.StageVisible) {
	case lifecycle.CrossOn:
	pauseChan <- play
	var err error
	buf, err = s.NewBuffer(image.Point{N, N})
	if err != nil {
	log.Fatal(err)
	}
	tex, err = s.NewTexture(image.Point{N, N})
	if err != nil {
	log.Fatal(err)
	}
	tex.Fill(tex.Bounds(), color.White, draw.Src)

	case lifecycle.CrossOff:
	pauseChan <- pause
	tex.Release()
	tex = nil
	buf.Release()
	buf = nil
	}

	case mouse.Event:
	if e.Button == mouse.ButtonLeft {
	buttonDown = e.Direction == mouse.DirPress
	}
	if !buttonDown {
	break
	}
	z := sz.Size()
	x := int(e.X) * N / z.X
	y := int(e.Y) * N / z.Y
	if x < 0 \|\| N <= x \|\| y < 0 \|\| N <= y {
	break
	}

	shared.mu.Lock()
	shared.mouseEvents = append(shared.mouseEvents, image.Point{x, y})
	shared.mu.Unlock()

	case paint.Event:
	publish = buf != nil

	case size.Event:
	sz = e

	case uploadEvent:
	shared.mu.Lock()
	if buf != nil {
	copy(buf.RGBA().Pix, shared.pix)
	publish = true
	}
	shared.uploadEventSent = false
	shared.mu.Unlock()

	if publish {
	tex.Upload(image.Point{}, buf, buf.Bounds())
	}

	case error:
	log.Print(e)
	}

	if publish {
	w.Scale(sz.Bounds(), tex, tex.Bounds(), draw.Src, nil)
	w.Publish()
	}
	}
	})
	}

	const (
	pause = false
	play = true
	)

	// pauseChan lets the UI event goroutine pause and play the CPU-intensive
	// simulation goroutine depending on whether the window is visible (e.g.
	// minimized). 64 should be large enough, in typical use, so that the former
	// doesn't ever block on the latter.
	var pauseChan = make(chan bool, 64)

	// uploadEvent signals that the shared pix slice should be uploaded to the
	// screen.Texture via the screen.Buffer.
	type uploadEvent struct{}

	var shared = struct {
	mu sync.Mutex
	uploadEventSent bool
	mouseEvents []image.Point
	pix []byte
	}{
	pix: make([]byte, 4NN),
	}

	func simulate(q screen.EventDeque) {
	var (
	dens, densPrev array
	u, uPrev array
	v, vPrev array
	xPrev, yPrev int
	havePrevLoc bool
	)

	ticker := time.NewTicker(tickDuration)
	var tickerC <-chan time.Time
	for {
	select {
	case p := <-pauseChan:
	if p == pause {
	tickerC = nil
	} else {
	tickerC = ticker.C
	}
	continue
	case <-tickerC:
	}

	shared.mu.Lock()
	for _, p := range shared.mouseEvents {
	dens[p.X+1][p.Y] = source
	if havePrevLoc {
	u[p.X+1][p.Y+1] = force * float32(p.X-xPrev)
	v[p.X+1][p.Y+1] = force * float32(p.Y-yPrev)
	}
	xPrev, yPrev, havePrevLoc = p.X, p.Y, true
	}
	shared.mouseEvents = shared.mouseEvents[:0]
	shared.mu.Unlock()

	velStep(&u, &v, &uPrev, &vPrev)
	densStep(&dens, &densPrev, &u, &v)

	// This fade isn't part of Stam's GDC03 paper, but it looks nice.
	for i := range dens {
	for j := range dens[i] {
	dens[i][j] *= fade
	}
	}

	shared.mu.Lock()
	for y := 0; y < N; y++ {
	for x := 0; x < N; x++ {
	d := int32(dens[x+1][y+1] * 0xff)
	if d < 0 {
	d = 0
	} else if d > 0xff {
	d = 0xff
	}
	v := 255 - uint8(d)
	p := (Ny + x) 4
	shared.pix[p+0] = v
	shared.pix[p+1] = v
	shared.pix[p+2] = v
	shared.pix[p+3] = 0xff
	}
	}
	uploadEventSent := shared.uploadEventSent
	shared.uploadEventSent = true
	shared.mu.Unlock()

	if !uploadEventSent {
	q.Send(uploadEvent{})
	}
	}
	}

	// All of the remaining code more or less comes from Stam's GDC03 paper.

	type array [N + 2][N + 2]float32

	func addSource(x, s *array) {
	for i := range x {
	for j := range x[i] {
	x[i][j] += dt * s[i][j]
	}
	}
	}

	func setBnd(b int, x *array) {
	switch b {
	case 0:
	for i := 1; i <= N; i++ {
	x[0+0][i] = +x[1][i]
	x[N+1][i] = +x[N][i]
	x[i][0+0] = +x[i][1]
	x[i][N+1] = +x[i][N]
	}
	case 1:
	for i := 1; i <= N; i++ {
	x[0+0][i] = -x[1][i]
	x[N+1][i] = -x[N][i]
	x[i][0+0] = +x[i][1]
	x[i][N+1] = +x[i][N]
	}
	case 2:
	for i := 1; i <= N; i++ {
	x[0+0][i] = +x[1][i]
	x[N+1][i] = +x[N][i]
	x[i][0+0] = -x[i][1]
	x[i][N+1] = -x[i][N]
	}
	}
	x[0+0][0+0] = 0.5 * (x[1][0+0] + x[0+0][1])
	x[0+0][N+1] = 0.5 * (x[1][N+1] + x[0+0][N])
	x[N+1][0+0] = 0.5 * (x[N][0+0] + x[N+1][1])
	x[N+1][N+1] = 0.5 * (x[N][N+1] + x[N+1][N])
	}

	func linSolve(b int, x, x0 *array, a, c float32) {
	// This if block isn't part of Stam's GDC03 paper, but it's a nice
	// optimization when the diff diffusion parameter is zero.
	if a == 0 && c == 1 {
	for i := 1; i <= N; i++ {
	for j := 1; j <= N; j++ {
	x[i][j] = x0[i][j]
	}
	}
	setBnd(b, x)
	return
	}

	invC := 1 / c
	for k := 0; k < iterations; k++ {
	for i := 1; i <= N; i++ {
	for j := 1; j <= N; j++ {
	x[i][j] = (x0[i][j] + a(x[i-1][j]+x[i+1][j]+x[i][j-1]+x[i][j+1])) invC
	}
	}
	setBnd(b, x)
	}
	}

	func diffuse(b int, x, x0 *array, diff float32) {
	a := dt * diff * N * N
	linSolve(b, x, x0, a, 1+4*a)
	}

	func advect(b int, d, d0, u, v *array) {
	const dt0 = dt * N
	for i := 1; i <= N; i++ {
	for j := 1; j <= N; j++ {
	x := float32(i) - dt0*u[i][j]
	if x < 0.5 {
	x = 0.5
	}
	if x > N+0.5 {
	x = N + 0.5
	}
	i0 := int(x)
	i1 := i0 + 1

	y := float32(j) - dt0*v[i][j]
	if y < 0.5 {
	y = 0.5
	}
	if y > N+0.5 {
	y = N + 0.5
	}
	j0 := int(y)
	j1 := j0 + 1

	s1 := x - float32(i0)
	s0 := 1 - s1
	t1 := y - float32(j0)
	t0 := 1 - t1
	d[i][j] = s0(t0d0[i0][j0]+t1d0[i0][j1]) + s1(t0d0[i1][j0]+t1d0[i1][j1])
	}
	}
	setBnd(b, d)
	}

	func project(u, v, p, div *array) {
	for i := 1; i <= N; i++ {
	for j := 1; j <= N; j++ {
	div[i][j] = (u[i+1][j] - u[i-1][j] + v[i][j+1] - v[i][j-1]) / (-2 * N)
	p[i][j] = 0
	}
	}
	setBnd(0, div)
	setBnd(0, p)
	linSolve(0, p, div, 1, 4)
	for i := 1; i <= N; i++ {
	for j := 1; j <= N; j++ {
	u[i][j] -= (N / 2) * (p[i+1][j+0] - p[i-1][j+0])
	v[i][j] -= (N / 2) * (p[i+0][j+1] - p[i+0][j-1])
	}
	}
	setBnd(1, u)
	setBnd(2, v)
	}

	func velStep(u, v, u0, v0 *array) {
	addSource(u, u0)
	addSource(v, v0)
	u0, u = u, u0
	diffuse(1, u, u0, visc)
	v0, v = v, v0
	diffuse(2, v, v0, visc)
	project(u, v, u0, v0)
	u0, u = u, u0
	v0, v = v, v0
	advect(1, u, u0, u0, v0)
	advect(2, v, v0, u0, v0)
	project(u, v, u0, v0)
	}

	func densStep(x, x0, u, v *array) {
	addSource(x, x0)
	x0, x = x, x0
	diffuse(0, x, x0, diff)
	x0, x = x, x0
	advect(0, x, x0, u, v)
	}