package fireworks import ( "math" "math/rand" "time" "github.com/maaslalani/confetty/array" "github.com/maaslalani/confetty/simulation" tea "github.com/charmbracelet/bubbletea" "github.com/charmbracelet/lipgloss" ) const ( framesPerSecond = 30.0 numParticles = 50 ) var ( colors = []string{"#a864fd", "#29cdff", "#78ff44", "#ff718d", "#fdff6a"} characters = []string{"+", "*", "•"} head_char = "▄" tail_char = "│" ) type frameMsg time.Time func animate() tea.Cmd { return tea.Tick(time.Second/framesPerSecond, func(t time.Time) tea.Msg { return frameMsg(t) }) } type model struct { system *simulation.System } func SpawnShoot(width, height int) *simulation.Particle { color := lipgloss.Color(array.Sample(colors)) v := float64(rand.Intn(15) + 15.0) x := rand.Float64() * float64(width) p := simulation.Particle{ Physics: simulation.NewProjectile( simulation.FPS(framesPerSecond), simulation.Point{X: x, Y: float64(height)}, simulation.Vector{X: 0, Y: -v}, simulation.Vector(simulation.TerminalGravity), ), Char: lipgloss.NewStyle().Foreground(color).Render(head_char), TailChar: lipgloss.NewStyle().Foreground(color).Render(tail_char), Shooting: true, ExplosionCall: SpawnExplosion, } return &p } func SpawnExplosion(x, y float64, width, height int) []*simulation.Particle { color := lipgloss.Color(array.Sample(colors)) v := float64(rand.Intn(10) + 20.0) particles := []*simulation.Particle{} for i := 0; i < numParticles; i++ { p := simulation.Particle{ Physics: simulation.NewProjectile( simulation.FPS(framesPerSecond), simulation.Point{X: x, Y: y}, simulation.Vector{X: math.Cos(float64(i)) * v, Y: math.Sin(float64(i)) * v / 2}, simulation.Vector(simulation.TerminalGravity), ), Char: lipgloss.NewStyle().Foreground(color).Render(array.Sample(characters)), Shooting: false, } particles = append(particles, &p) } return particles } func InitialModel() model { return model{system: &simulation.System{ Particles: []*simulation.Particle{}, Frame: simulation.Frame{}, }} } // Init initializes the confetti after a small delay func (m model) Init() tea.Cmd { return animate() } // Update updates the model every frame, it handles the animation loop and // updates the particle physics every frame func (m model) Update(msg tea.Msg) (tea.Model, tea.Cmd) { switch msg := msg.(type) { case tea.KeyMsg: switch msg.String() { case "ctrl+c", "q": return m, tea.Quit } m.system.Particles = append(m.system.Particles, SpawnShoot(m.system.Frame.Width, m.system.Frame.Height)) return m, nil case frameMsg: m.system.Update() return m, animate() case tea.WindowSizeMsg: if m.system.Frame.Width == 0 && m.system.Frame.Height == 0 { // For the first frameMsg spawn a system of particles m.system.Particles = append(m.system.Particles, SpawnShoot(msg.Width, msg.Height)) } m.system.Frame.Width = msg.Width m.system.Frame.Height = msg.Height return m, nil default: return m, nil } } // View displays all the particles on the screen func (m model) View() string { return m.system.Render() }