packages/flutter/lib/src/physics/gravity_simulation.dart - external/github.com/flutter/flutter - Git at Google

 // Copyright 2014 The Flutter Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 import 'package:flutter/foundation.dart';

 import 'simulation.dart';

 // Examples can assume:
 // late AnimationController _controller;

 /// A simulation that applies a constant accelerating force.
 ///
 /// Models a particle that follows Newton's second law of motion. The simulation
 /// ends when the position exceeds a defined threshold.
 ///
 /// {@tool snippet}
 ///
 /// This method triggers an [AnimationController] (a previously constructed
 /// `_controller` field) to simulate a fall of 300 pixels.
 ///
 /// ```dart
 /// void _startFall() {
 ///   _controller.animateWith(GravitySimulation(
 ///     10.0, // acceleration, pixels per second per second
 ///     0.0, // starting position, pixels
 ///     300.0, // ending position, pixels
 ///     0.0, // starting velocity, pixels per second
 ///   ));
 /// }
 /// ```
 /// {@end-tool}
 ///
 /// This [AnimationController] could be used with an [AnimatedBuilder] to
 /// animate the position of a child as if it was falling.
 ///
 /// The end distance threshold (the constructor's third argument) must be
 /// specified as a positive number but can be reached in either the positive or
 /// negative direction. For example (assuming negative numbers represent higher
 /// physical positions than positive numbers, as is the case with the normal
 /// [Canvas] coordinate system), if the acceleration is positive ("down") the
 /// starting velocity is negative ("up"), and the starting distance is zero, the
 /// particle will climb from the origin, reach a plateau, then fall back towards
 /// and past the origin. If the end distance threshold is less than the height
 /// of the plateau, then the simulation will end during the climb; otherwise, it
 /// will end during the fall, after the particle travels below the origin by
 /// that distance.
 ///
 /// See also:
 ///
 ///  * [Curves.bounceOut], a [Curve] that has a similar aesthetics but includes
 ///    a bouncing effect.
 class GravitySimulation extends Simulation {
   /// Creates a [GravitySimulation] using the given arguments, which are,
   /// respectively: an acceleration that is to be applied continually over time;
   /// an initial position relative to an origin; the magnitude of the distance
   /// from that origin beyond which (in either direction) to consider the
   /// simulation to be "done", which must be positive; and an initial velocity.
   ///
   /// The initial position and maximum distance are measured in arbitrary length
   /// units L from an arbitrary origin. The units will match those used for [x].
   ///
   /// The time unit T used for the arguments to [x], [dx], and [isDone],
   /// combined with the aforementioned length unit, together determine the units
   /// that must be used for the velocity and acceleration arguments: L/T and
   /// L/T² respectively. The same units of velocity are used for the velocity
   /// obtained from [dx].
   GravitySimulation(
     double acceleration,
     double distance,
     double endDistance,
     double velocity,
   ) : assert(acceleration != null),
       assert(distance != null),
       assert(velocity != null),
       assert(endDistance != null),
       assert(endDistance >= 0),
       _a = acceleration,
       _x = distance,
       _v = velocity,
       _end = endDistance;

   final double _x;
   final double _v;
   final double _a;
   final double _end;

   @override
   double x(double time) => _x + _v * time + 0.5 * _a * time * time;

   @override
   double dx(double time) => _v + time * _a;

   @override
   bool isDone(double time) => x(time).abs() >= _end;

   @override
   String toString() => '${objectRuntimeType(this, 'GravitySimulation')}(g: ${_a.toStringAsFixed(1)}, x₀: ${_x.toStringAsFixed(1)}, dx₀: ${_v.toStringAsFixed(1)}, xₘₐₓ: ±${_end.toStringAsFixed(1)})';
 }
	// Copyright 2014 The Flutter Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	import 'package:flutter/foundation.dart';

	import 'simulation.dart';

	// Examples can assume:
	// late AnimationController _controller;

	/// A simulation that applies a constant accelerating force.
	///
	/// Models a particle that follows Newton's second law of motion. The simulation
	/// ends when the position exceeds a defined threshold.
	///
	/// {@tool snippet}
	///
	/// This method triggers an [AnimationController] (a previously constructed
	/// `_controller` field) to simulate a fall of 300 pixels.
	///
	/// ```dart
	/// void _startFall() {
	/// _controller.animateWith(GravitySimulation(
	/// 10.0, // acceleration, pixels per second per second
	/// 0.0, // starting position, pixels
	/// 300.0, // ending position, pixels
	/// 0.0, // starting velocity, pixels per second
	/// ));
	/// }
	/// ```
	/// {@end-tool}
	///
	/// This [AnimationController] could be used with an [AnimatedBuilder] to
	/// animate the position of a child as if it was falling.
	///
	/// The end distance threshold (the constructor's third argument) must be
	/// specified as a positive number but can be reached in either the positive or
	/// negative direction. For example (assuming negative numbers represent higher
	/// physical positions than positive numbers, as is the case with the normal
	/// [Canvas] coordinate system), if the acceleration is positive ("down") the
	/// starting velocity is negative ("up"), and the starting distance is zero, the
	/// particle will climb from the origin, reach a plateau, then fall back towards
	/// and past the origin. If the end distance threshold is less than the height
	/// of the plateau, then the simulation will end during the climb; otherwise, it
	/// will end during the fall, after the particle travels below the origin by
	/// that distance.
	///
	/// See also:
	///
	/// * [Curves.bounceOut], a [Curve] that has a similar aesthetics but includes
	/// a bouncing effect.
	class GravitySimulation extends Simulation {
	/// Creates a [GravitySimulation] using the given arguments, which are,
	/// respectively: an acceleration that is to be applied continually over time;
	/// an initial position relative to an origin; the magnitude of the distance
	/// from that origin beyond which (in either direction) to consider the
	/// simulation to be "done", which must be positive; and an initial velocity.
	///
	/// The initial position and maximum distance are measured in arbitrary length
	/// units L from an arbitrary origin. The units will match those used for [x].
	///
	/// The time unit T used for the arguments to [x], [dx], and [isDone],
	/// combined with the aforementioned length unit, together determine the units
	/// that must be used for the velocity and acceleration arguments: L/T and
	/// L/T² respectively. The same units of velocity are used for the velocity
	/// obtained from [dx].
	GravitySimulation(
	double acceleration,
	double distance,
	double endDistance,
	double velocity,
	) : assert(acceleration != null),
	assert(distance != null),
	assert(velocity != null),
	assert(endDistance != null),
	assert(endDistance >= 0),
	_a = acceleration,
	_x = distance,
	_v = velocity,
	_end = endDistance;

	final double _x;
	final double _v;
	final double _a;
	final double _end;

	@override
	double x(double time) => _x + _v * time + 0.5 * _a * time * time;

	@override
	double dx(double time) => _v + time * _a;

	@override
	bool isDone(double time) => x(time).abs() >= _end;

	@override
	String toString() => '${objectRuntimeType(this, 'GravitySimulation')}(g: ${_a.toStringAsFixed(1)}, x₀: ${_x.toStringAsFixed(1)}, dx₀: ${_v.toStringAsFixed(1)}, xₘₐₓ: ±${_end.toStringAsFixed(1)})';
	}