dev/tools/vitool/lib/vitool.dart - mirrors/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 'dart:io';
 import 'dart:math';

 import 'package:collection/collection.dart';
 import 'package:meta/meta.dart';
 import 'package:vector_math/vector_math_64.dart';
 import 'package:xml/xml.dart';

 // String to use for a single indentation.
 const String kIndent = '  ';

 /// Represents an animation, and provides logic to generate dart code for it.
 class Animation {
   const Animation(this.size, this.paths);

   factory Animation.fromFrameData(List<FrameData> frames) {
     _validateFramesData(frames);
     final Point<double> size = frames[0].size;
     final List<PathAnimation> paths = <PathAnimation>[];
     for (int i = 0; i < frames[0].paths.length; i += 1) {
       paths.add(PathAnimation.fromFrameData(frames, i));
     }
     return Animation(size, paths);
   }

   /// The size of the animation (width, height) in pixels.
   final Point<double> size;

   /// List of paths in the animation.
   final List<PathAnimation> paths;

   static void _validateFramesData(List<FrameData> frames) {
     final Point<double> size = frames[0].size;
     final int numPaths = frames[0].paths.length;
     for (int i = 0; i < frames.length; i += 1) {
       final FrameData frame = frames[i];
       if (size != frame.size) {
         throw Exception(
             'All animation frames must have the same size,\n'
             'first frame size was: (${size.x}, ${size.y})\n'
             'frame $i size was: (${frame.size.x}, ${frame.size.y})'
         );
       }
       if (numPaths != frame.paths.length) {
         throw Exception(
             'All animation frames must have the same number of paths,\n'
             'first frame has $numPaths paths\n'
             'frame $i has ${frame.paths.length} paths'
         );
       }
     }
   }

   String toDart(String className, String varName) {
     final StringBuffer sb = StringBuffer();
     sb.write('const $className $varName = const $className(\n');
     sb.write('${kIndent}const Size(${size.x}, ${size.y}),\n');
     sb.write('${kIndent}const <_PathFrames>[\n');
     for (final PathAnimation path in paths) {
       sb.write(path.toDart());
     }
     sb.write('$kIndent],\n');
     sb.write(');');
     return sb.toString();
   }
 }

 /// Represents the animation of a single path.
 class PathAnimation {
   const PathAnimation(this.commands, {required this.opacities});

   factory PathAnimation.fromFrameData(List<FrameData> frames, int pathIdx) {
     if (frames.isEmpty) {
       return const PathAnimation(<PathCommandAnimation>[], opacities: <double>[]);
     }

     final List<PathCommandAnimation> commands = <PathCommandAnimation>[];
     for (int commandIdx = 0; commandIdx < frames[0].paths[pathIdx].commands.length; commandIdx += 1) {
       final int numPointsInCommand = frames[0].paths[pathIdx].commands[commandIdx].points.length;
       final List<List<Point<double>>> points = List<List<Point<double>>>.filled(numPointsInCommand, <Point<double>>[]);
       final String commandType = frames[0].paths[pathIdx].commands[commandIdx].type;
       for (int i = 0; i < frames.length; i += 1) {
         final FrameData frame = frames[i];
         final String currentCommandType = frame.paths[pathIdx].commands[commandIdx].type;
         if (commandType != currentCommandType) {
           throw Exception(
               'Paths must be built from the same commands in all frames '
               "command $commandIdx at frame 0 was of type '$commandType' "
               "command $commandIdx at frame $i was of type '$currentCommandType'"
           );
         }
         for (int j = 0; j < numPointsInCommand; j += 1) {
           points[j].add(frame.paths[pathIdx].commands[commandIdx].points[j]);
         }
       }
       commands.add(PathCommandAnimation(commandType, points));
     }

     final List<double> opacities =
       frames.map<double>((FrameData d) => d.paths[pathIdx].opacity).toList();

     return PathAnimation(commands, opacities: opacities);
   }

   /// List of commands for drawing the path.
   final List<PathCommandAnimation> commands;
   /// The path opacity for each animation frame.
   final List<double> opacities;

   @override
   String toString() {
     return 'PathAnimation(commands: $commands, opacities: $opacities)';
   }

   String toDart() {
     final StringBuffer sb = StringBuffer();
     sb.write('${kIndent * 2}const _PathFrames(\n');
     sb.write('${kIndent * 3}opacities: const <double>[\n');
     for (final double opacity in opacities) {
       sb.write('${kIndent * 4}$opacity,\n');
     }
     sb.write('${kIndent * 3}],\n');
     sb.write('${kIndent * 3}commands: const <_PathCommand>[\n');
     for (final PathCommandAnimation command in commands) {
       sb.write(command.toDart());
     }
     sb.write('${kIndent * 3}],\n');
     sb.write('${kIndent * 2}),\n');
     return sb.toString();
   }
 }

 /// Represents the animation of a single path command.
 class PathCommandAnimation {
   const PathCommandAnimation(this.type, this.points);

   /// The command type.
   final String type;

   /// A matrix with the command's points in different frames.
   ///
   /// points[i][j] is the i-th point of the command at frame j.
   final List<List<Point<double>>> points;

   @override
   String toString() {
     return 'PathCommandAnimation(type: $type, points: $points)';
   }

   String toDart() {
     String dartCommandClass;
     switch (type) {
       case 'M':
         dartCommandClass = '_PathMoveTo';
         break;
       case 'C':
         dartCommandClass = '_PathCubicTo';
         break;
       case 'L':
         dartCommandClass = '_PathLineTo';
         break;
       case 'Z':
         dartCommandClass = '_PathClose';
         break;
       default:
         throw Exception('unsupported path command: $type');
     }
     final StringBuffer sb = StringBuffer();
     sb.write('${kIndent * 4}const $dartCommandClass(\n');
     for (final List<Point<double>> pointFrames in points) {
       sb.write('${kIndent * 5}const <Offset>[\n');
       for (final Point<double> point in pointFrames) {
         sb.write('${kIndent * 6}const Offset(${point.x}, ${point.y}),\n');
       }
       sb.write('${kIndent * 5}],\n');
     }
     sb.write('${kIndent * 4}),\n');
     return sb.toString();
   }
 }

 /// Interprets some subset of an SVG file.
 ///
 /// Recursively goes over the SVG tree, applying transforms and opacities,
 /// and build a FrameData which is a flat representation of the paths in the SVG
 /// file, after applying transformations and converting relative coordinates to
 /// absolute.
 ///
 /// This does not support the SVG specification, but is just built to
 /// support SVG files exported by a specific tool the motion design team is
 /// using.
 FrameData interpretSvg(String svgFilePath) {
   final File file = File(svgFilePath);
   final String fileData = file.readAsStringSync();
   final XmlElement svgElement = _extractSvgElement(XmlDocument.parse(fileData));
   final double width = parsePixels(_extractAttr(svgElement, 'width')).toDouble();
   final double height = parsePixels(_extractAttr(svgElement, 'height')).toDouble();

   final List<SvgPath> paths =
     _interpretSvgGroup(svgElement.children, _Transform());
   return FrameData(Point<double>(width, height), paths);
 }

 List<SvgPath> _interpretSvgGroup(List<XmlNode> children, _Transform transform) {
   final List<SvgPath> paths = <SvgPath>[];
   for (final XmlNode node in children) {
     if (node.nodeType != XmlNodeType.ELEMENT) {
       continue;
     }
     final XmlElement element = node as XmlElement;

     if (element.name.local == 'path') {
       paths.add(SvgPath.fromElement(element)._applyTransform(transform));
     }

     if (element.name.local == 'g') {
       double opacity = transform.opacity;
       if (_hasAttr(element, 'opacity')) {
         opacity *= double.parse(_extractAttr(element, 'opacity'));
       }

       Matrix3 transformMatrix = transform.transformMatrix;
       if (_hasAttr(element, 'transform')) {
         transformMatrix = transformMatrix.multiplied(
           _parseSvgTransform(_extractAttr(element, 'transform')));
       }

       final _Transform subtreeTransform = _Transform(
         transformMatrix: transformMatrix,
         opacity: opacity,
       );
       paths.addAll(_interpretSvgGroup(element.children, subtreeTransform));
     }
   }
   return paths;
 }

 // Given a points list in the form e.g: "25.0, 1.0 12.0, 12.0 23.0, 9.0" matches
 // the coordinated of the first point and the rest of the string, for the
 // example above:
 // group 1 will match "25.0"
 // group 2 will match "1.0"
 // group 3 will match "12.0, 12.0 23.0, 9.0"
 //
 // Commas are optional.
 final RegExp _pointMatcher = RegExp(r'^ *([\-\.0-9]+) *,? *([\-\.0-9]+)(.*)');

 /// Parse a string with a list of points, e.g:
 /// '25.0, 1.0 12.0, 12.0 23.0, 9.0' will be parsed to:
 /// [Point(25.0, 1.0), Point(12.0, 12.0), Point(23.0, 9.0)].
 ///
 /// Commas are optional.
 List<Point<double>> parsePoints(String points) {
   String unParsed = points;
   final List<Point<double>> result = <Point<double>>[];
   while (unParsed.isNotEmpty && _pointMatcher.hasMatch(unParsed)) {
     final Match m = _pointMatcher.firstMatch(unParsed)!;
     result.add(Point<double>(
         double.parse(m.group(1)!),
         double.parse(m.group(2)!),
     ));
     unParsed = m.group(3)!;
   }
   return result;
 }

 /// Data for a single animation frame.
 @immutable
 class FrameData {
   const FrameData(this.size, this.paths);

   final Point<double> size;
   final List<SvgPath> paths;

   @override
   bool operator ==(Object other) {
     if (other.runtimeType != runtimeType) {
       return false;
     }
     return other is FrameData
         && other.size == size
         && const ListEquality<SvgPath>().equals(other.paths, paths);
   }

   @override
   int get hashCode => Object.hash(size, Object.hashAll(paths));

   @override
   String toString() {
     return 'FrameData(size: $size, paths: $paths)';
   }
 }

 /// Represents an SVG path element.
 @immutable
 class SvgPath {
   const SvgPath(this.id, this.commands, {this.opacity = 1.0});

   final String id;
   final List<SvgPathCommand> commands;
   final double opacity;

   static const String _pathCommandAtom = r' *([a-zA-Z]) *([\-\.0-9 ,]*)';
   static final RegExp _pathCommandValidator = RegExp('^($_pathCommandAtom)*\$');
   static final RegExp _pathCommandMatcher = RegExp(_pathCommandAtom);

   static SvgPath fromElement(XmlElement pathElement) {
     assert(pathElement.name.local == 'path');
     final String id = _extractAttr(pathElement, 'id');
     final String dAttr = _extractAttr(pathElement, 'd');
     final List<SvgPathCommand> commands = <SvgPathCommand>[];
     final SvgPathCommandBuilder commandsBuilder = SvgPathCommandBuilder();
     if (!_pathCommandValidator.hasMatch(dAttr)) {
       throw Exception('illegal or unsupported path d expression: $dAttr');
     }
     for (final Match match in _pathCommandMatcher.allMatches(dAttr)) {
       final String commandType = match.group(1)!;
       final String pointStr = match.group(2)!;
       commands.add(commandsBuilder.build(commandType, parsePoints(pointStr)));
     }
     return SvgPath(id, commands);
   }

   SvgPath _applyTransform(_Transform transform) {
     final List<SvgPathCommand> transformedCommands =
       commands.map<SvgPathCommand>((SvgPathCommand c) => c._applyTransform(transform)).toList();
     return SvgPath(id, transformedCommands, opacity: opacity * transform.opacity);
   }

   @override
   bool operator ==(Object other) {
     if (other.runtimeType != runtimeType) {
       return false;
     }
     return other is SvgPath
         && other.id == id
         && other.opacity == opacity
         && const ListEquality<SvgPathCommand>().equals(other.commands, commands);
   }

   @override
   int get hashCode => Object.hash(id, Object.hashAll(commands), opacity);

   @override
   String toString() {
     return 'SvgPath(id: $id, opacity: $opacity, commands: $commands)';
   }

 }

 /// Represents a single SVG path command from an SVG d element.
 ///
 /// This class normalizes all the 'd' commands into a single type, that has
 /// a command type and a list of points.
 ///
 /// Some examples of how d commands translated to SvgPathCommand:
 ///   * "M 0.0, 1.0" => SvgPathCommand('M', [Point(0.0, 1.0)])
 ///   * "Z" => SvgPathCommand('Z', [])
 ///   * "C 1.0, 1.0 2.0, 2.0 3.0, 3.0" SvgPathCommand('C', [Point(1.0, 1.0),
 ///      Point(2.0, 2.0), Point(3.0, 3.0)])
 @immutable
 class SvgPathCommand {
   const SvgPathCommand(this.type, this.points);

   /// The command type.
   final String type;

   /// List of points used by this command.
   final List<Point<double>> points;

   SvgPathCommand _applyTransform(_Transform transform) {
     final List<Point<double>> transformedPoints =
     _vector3ArrayToPoints(
         transform.transformMatrix.applyToVector3Array(
             _pointsToVector3Array(points)
         )
     );
     return SvgPathCommand(type, transformedPoints);
   }

   @override
   bool operator ==(Object other) {
     if (other.runtimeType != runtimeType) {
       return false;
     }
     return other is SvgPathCommand
         && other.type == type
         && const ListEquality<Point<double>>().equals(other.points, points);
   }

   @override
   int get hashCode => Object.hash(type, Object.hashAll(points));

   @override
   String toString() {
     return 'SvgPathCommand(type: $type, points: $points)';
   }
 }

 class SvgPathCommandBuilder {
   static const Map<String, void> kRelativeCommands = <String, void> {
     'c': null,
     'l': null,
     'm': null,
     't': null,
     's': null,
   };

   Point<double> lastPoint = const Point<double>(0.0, 0.0);
   Point<double> subPathStartPoint = const Point<double>(0.0, 0.0);

   SvgPathCommand build(String type, List<Point<double>> points) {
     List<Point<double>> absPoints = points;
     if (_isRelativeCommand(type)) {
       absPoints = points.map<Point<double>>((Point<double> p) => p + lastPoint).toList();
     }

     if (type == 'M' || type == 'm') {
       subPathStartPoint = absPoints.last;
     }

     if (type == 'Z' || type == 'z') {
       lastPoint = subPathStartPoint;
     } else {
       lastPoint = absPoints.last;
     }

     return SvgPathCommand(type.toUpperCase(), absPoints);
   }

   static bool _isRelativeCommand(String type) {
     return kRelativeCommands.containsKey(type);
   }
 }

 List<double> _pointsToVector3Array(List<Point<double>> points) {
   final List<double> result = List<double>.filled(points.length * 3, 0.0);
   for (int i = 0; i < points.length; i += 1) {
     result[i * 3] = points[i].x;
     result[i * 3 + 1] = points[i].y;
     result[i * 3 + 2] = 1.0;
   }
   return result;
 }

 List<Point<double>> _vector3ArrayToPoints(List<double> vector) {
   final int numPoints = (vector.length / 3).floor();
   final List<Point<double>> points = <Point<double>>[
     for (int i = 0; i < numPoints; i += 1)
       Point<double>(vector[i*3], vector[i*3 + 1]),
   ];
   return points;
 }

 /// Represents a transformation to apply on an SVG subtree.
 ///
 /// This includes more transforms than the ones described by the SVG transform
 /// attribute, e.g opacity.
 class _Transform {

   /// Constructs a new _Transform, default arguments create a no-op transform.
   _Transform({Matrix3? transformMatrix, this.opacity = 1.0}) :
       transformMatrix = transformMatrix ?? Matrix3.identity();

   final Matrix3 transformMatrix;
   final double opacity;

   _Transform applyTransform(_Transform transform) {
     return _Transform(
         transformMatrix: transform.transformMatrix.multiplied(transformMatrix),
         opacity: transform.opacity * opacity,
     );
   }
 }


 const String _transformCommandAtom = r' *([^(]+)\(([^)]*)\)';
 final RegExp _transformValidator = RegExp('^($_transformCommandAtom)*\$');
 final RegExp _transformCommand = RegExp(_transformCommandAtom);

 Matrix3 _parseSvgTransform(String transform) {
   if (!_transformValidator.hasMatch(transform)) {
     throw Exception('illegal or unsupported transform: $transform');
   }
   final Iterable<Match> matches =_transformCommand.allMatches(transform).toList().reversed;
   Matrix3 result = Matrix3.identity();
   for (final Match m in matches) {
     final String command = m.group(1)!;
     final String params = m.group(2)!;
     if (command == 'translate') {
       result = _parseSvgTranslate(params).multiplied(result);
       continue;
     }
     if (command == 'scale') {
       result = _parseSvgScale(params).multiplied(result);
       continue;
     }
     if (command == 'rotate') {
       result = _parseSvgRotate(params).multiplied(result);
       continue;
     }
     throw Exception('unimplemented transform: $command');
   }
   return result;
 }

 final RegExp _valueSeparator = RegExp('( *, *| +)');

 Matrix3 _parseSvgTranslate(String paramsStr) {
   final List<String> params = paramsStr.split(_valueSeparator);
   assert(params.isNotEmpty);
   assert(params.length <= 2);
   final double x = double.parse(params[0]);
   final double y = params.length < 2 ? 0 : double.parse(params[1]);
   return _matrix(1.0, 0.0, 0.0, 1.0, x, y);
 }

 Matrix3 _parseSvgScale(String paramsStr) {
   final List<String> params = paramsStr.split(_valueSeparator);
   assert(params.isNotEmpty);
   assert(params.length <= 2);
   final double x = double.parse(params[0]);
   final double y = params.length < 2 ? 0 : double.parse(params[1]);
   return _matrix(x, 0.0, 0.0, y, 0.0, 0.0);
 }

 Matrix3 _parseSvgRotate(String paramsStr) {
   final List<String> params = paramsStr.split(_valueSeparator);
   assert(params.length == 1);
   final double a = radians(double.parse(params[0]));
   return _matrix(cos(a), sin(a), -sin(a), cos(a), 0.0, 0.0);
 }

 Matrix3 _matrix(double a, double b, double c, double d, double e, double f) {
   return Matrix3(a, b, 0.0, c, d, 0.0, e, f, 1.0);
 }

 // Matches a pixels expression e.g "14px".
 // First group is just the number.
 final RegExp _pixelsExp = RegExp(r'^([0-9]+)px$');

 /// Parses a pixel expression, e.g "14px", and returns the number.
 /// Throws an [ArgumentError] if the given string doesn't match the pattern.
 int parsePixels(String pixels) {
   if (!_pixelsExp.hasMatch(pixels)) {
     throw ArgumentError(
       "illegal pixels expression: '$pixels'"
       ' (the tool currently only support pixel units).');
   }
   return int.parse(_pixelsExp.firstMatch(pixels)!.group(1)!);
 }

 String _extractAttr(XmlElement element, String name) {
   try {
     return element.attributes.singleWhere((XmlAttribute x) => x.name.local == name)
         .value;
   } catch (e) {
     throw ArgumentError(
         "Can't find a single '$name' attributes in ${element.name}, "
         'attributes were: ${element.attributes}'
     );
   }
 }

 bool _hasAttr(XmlElement element, String name) {
   return element.attributes.where((XmlAttribute a) => a.name.local == name).isNotEmpty;
 }

 XmlElement _extractSvgElement(XmlDocument document) {
   return document.children.singleWhere(
     (XmlNode node) => node.nodeType  == XmlNodeType.ELEMENT &&
       _asElement(node).name.local == 'svg'
   ) as XmlElement;
 }

 XmlElement _asElement(XmlNode node) => node as XmlElement;
	// 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 'dart:io';
	import 'dart:math';

	import 'package:collection/collection.dart';
	import 'package:meta/meta.dart';
	import 'package:vector_math/vector_math_64.dart';
	import 'package:xml/xml.dart';

	// String to use for a single indentation.
	const String kIndent = ' ';

	/// Represents an animation, and provides logic to generate dart code for it.
	class Animation {
	const Animation(this.size, this.paths);

	factory Animation.fromFrameData(List<FrameData> frames) {
	_validateFramesData(frames);
	final Point<double> size = frames[0].size;
	final List<PathAnimation> paths = <PathAnimation>[];
	for (int i = 0; i < frames[0].paths.length; i += 1) {
	paths.add(PathAnimation.fromFrameData(frames, i));
	}
	return Animation(size, paths);
	}

	/// The size of the animation (width, height) in pixels.
	final Point<double> size;

	/// List of paths in the animation.
	final List<PathAnimation> paths;

	static void _validateFramesData(List<FrameData> frames) {
	final Point<double> size = frames[0].size;
	final int numPaths = frames[0].paths.length;
	for (int i = 0; i < frames.length; i += 1) {
	final FrameData frame = frames[i];
	if (size != frame.size) {
	throw Exception(
	'All animation frames must have the same size,\n'
	'first frame size was: (${size.x}, ${size.y})\n'
	'frame $i size was: (${frame.size.x}, ${frame.size.y})'
	);
	}
	if (numPaths != frame.paths.length) {
	throw Exception(
	'All animation frames must have the same number of paths,\n'
	'first frame has $numPaths paths\n'
	'frame $i has ${frame.paths.length} paths'
	);
	}
	}
	}

	String toDart(String className, String varName) {
	final StringBuffer sb = StringBuffer();
	sb.write('const $className $varName = const $className(\n');
	sb.write('${kIndent}const Size(${size.x}, ${size.y}),\n');
	sb.write('${kIndent}const <_PathFrames>[\n');
	for (final PathAnimation path in paths) {
	sb.write(path.toDart());
	}
	sb.write('$kIndent],\n');
	sb.write(');');
	return sb.toString();
	}
	}

	/// Represents the animation of a single path.
	class PathAnimation {
	const PathAnimation(this.commands, {required this.opacities});

	factory PathAnimation.fromFrameData(List<FrameData> frames, int pathIdx) {
	if (frames.isEmpty) {
	return const PathAnimation(<PathCommandAnimation>[], opacities: <double>[]);
	}

	final List<PathCommandAnimation> commands = <PathCommandAnimation>[];
	for (int commandIdx = 0; commandIdx < frames[0].paths[pathIdx].commands.length; commandIdx += 1) {
	final int numPointsInCommand = frames[0].paths[pathIdx].commands[commandIdx].points.length;
	final List<List<Point<double>>> points = List<List<Point<double>>>.filled(numPointsInCommand, <Point<double>>[]);
	final String commandType = frames[0].paths[pathIdx].commands[commandIdx].type;
	for (int i = 0; i < frames.length; i += 1) {
	final FrameData frame = frames[i];
	final String currentCommandType = frame.paths[pathIdx].commands[commandIdx].type;
	if (commandType != currentCommandType) {
	throw Exception(
	'Paths must be built from the same commands in all frames '
	"command $commandIdx at frame 0 was of type '$commandType' "
	"command $commandIdx at frame $i was of type '$currentCommandType'"
	);
	}
	for (int j = 0; j < numPointsInCommand; j += 1) {
	points[j].add(frame.paths[pathIdx].commands[commandIdx].points[j]);
	}
	}
	commands.add(PathCommandAnimation(commandType, points));
	}

	final List<double> opacities =
	frames.map<double>((FrameData d) => d.paths[pathIdx].opacity).toList();

	return PathAnimation(commands, opacities: opacities);
	}

	/// List of commands for drawing the path.
	final List<PathCommandAnimation> commands;
	/// The path opacity for each animation frame.
	final List<double> opacities;

	@override
	String toString() {
	return 'PathAnimation(commands: $commands, opacities: $opacities)';
	}

	String toDart() {
	final StringBuffer sb = StringBuffer();
	sb.write('${kIndent * 2}const _PathFrames(\n');
	sb.write('${kIndent * 3}opacities: const <double>[\n');
	for (final double opacity in opacities) {
	sb.write('${kIndent * 4}$opacity,\n');
	}
	sb.write('${kIndent * 3}],\n');
	sb.write('${kIndent * 3}commands: const <_PathCommand>[\n');
	for (final PathCommandAnimation command in commands) {
	sb.write(command.toDart());
	}
	sb.write('${kIndent * 3}],\n');
	sb.write('${kIndent * 2}),\n');
	return sb.toString();
	}
	}

	/// Represents the animation of a single path command.
	class PathCommandAnimation {
	const PathCommandAnimation(this.type, this.points);

	/// The command type.
	final String type;

	/// A matrix with the command's points in different frames.
	///
	/// points[i][j] is the i-th point of the command at frame j.
	final List<List<Point<double>>> points;

	@override
	String toString() {
	return 'PathCommandAnimation(type: $type, points: $points)';
	}

	String toDart() {
	String dartCommandClass;
	switch (type) {
	case 'M':
	dartCommandClass = '_PathMoveTo';
	break;
	case 'C':
	dartCommandClass = '_PathCubicTo';
	break;
	case 'L':
	dartCommandClass = '_PathLineTo';
	break;
	case 'Z':
	dartCommandClass = '_PathClose';
	break;
	default:
	throw Exception('unsupported path command: $type');
	}
	final StringBuffer sb = StringBuffer();
	sb.write('${kIndent * 4}const $dartCommandClass(\n');
	for (final List<Point<double>> pointFrames in points) {
	sb.write('${kIndent * 5}const <Offset>[\n');
	for (final Point<double> point in pointFrames) {
	sb.write('${kIndent * 6}const Offset(${point.x}, ${point.y}),\n');
	}
	sb.write('${kIndent * 5}],\n');
	}
	sb.write('${kIndent * 4}),\n');
	return sb.toString();
	}
	}

	/// Interprets some subset of an SVG file.
	///
	/// Recursively goes over the SVG tree, applying transforms and opacities,
	/// and build a FrameData which is a flat representation of the paths in the SVG
	/// file, after applying transformations and converting relative coordinates to
	/// absolute.
	///
	/// This does not support the SVG specification, but is just built to
	/// support SVG files exported by a specific tool the motion design team is
	/// using.
	FrameData interpretSvg(String svgFilePath) {
	final File file = File(svgFilePath);
	final String fileData = file.readAsStringSync();
	final XmlElement svgElement = _extractSvgElement(XmlDocument.parse(fileData));
	final double width = parsePixels(_extractAttr(svgElement, 'width')).toDouble();
	final double height = parsePixels(_extractAttr(svgElement, 'height')).toDouble();

	final List<SvgPath> paths =
	_interpretSvgGroup(svgElement.children, _Transform());
	return FrameData(Point<double>(width, height), paths);
	}

	List<SvgPath> _interpretSvgGroup(List<XmlNode> children, _Transform transform) {
	final List<SvgPath> paths = <SvgPath>[];
	for (final XmlNode node in children) {
	if (node.nodeType != XmlNodeType.ELEMENT) {
	continue;
	}
	final XmlElement element = node as XmlElement;

	if (element.name.local == 'path') {
	paths.add(SvgPath.fromElement(element)._applyTransform(transform));
	}

	if (element.name.local == 'g') {
	double opacity = transform.opacity;
	if (_hasAttr(element, 'opacity')) {
	opacity *= double.parse(_extractAttr(element, 'opacity'));
	}

	Matrix3 transformMatrix = transform.transformMatrix;
	if (_hasAttr(element, 'transform')) {
	transformMatrix = transformMatrix.multiplied(
	_parseSvgTransform(_extractAttr(element, 'transform')));
	}

	final _Transform subtreeTransform = _Transform(
	transformMatrix: transformMatrix,
	opacity: opacity,
	);
	paths.addAll(_interpretSvgGroup(element.children, subtreeTransform));
	}
	}
	return paths;
	}

	// Given a points list in the form e.g: "25.0, 1.0 12.0, 12.0 23.0, 9.0" matches
	// the coordinated of the first point and the rest of the string, for the
	// example above:
	// group 1 will match "25.0"
	// group 2 will match "1.0"
	// group 3 will match "12.0, 12.0 23.0, 9.0"
	//
	// Commas are optional.
	final RegExp _pointMatcher = RegExp(r'^ ([\-\.0-9]+) ,? ([\-\.0-9]+)(.)');

	/// Parse a string with a list of points, e.g:
	/// '25.0, 1.0 12.0, 12.0 23.0, 9.0' will be parsed to:
	/// [Point(25.0, 1.0), Point(12.0, 12.0), Point(23.0, 9.0)].
	///
	/// Commas are optional.
	List<Point<double>> parsePoints(String points) {
	String unParsed = points;
	final List<Point<double>> result = <Point<double>>[];
	while (unParsed.isNotEmpty && _pointMatcher.hasMatch(unParsed)) {
	final Match m = _pointMatcher.firstMatch(unParsed)!;
	result.add(Point<double>(
	double.parse(m.group(1)!),
	double.parse(m.group(2)!),
	));
	unParsed = m.group(3)!;
	}
	return result;
	}

	/// Data for a single animation frame.
	@immutable
	class FrameData {
	const FrameData(this.size, this.paths);

	final Point<double> size;
	final List<SvgPath> paths;

	@override
	bool operator ==(Object other) {
	if (other.runtimeType != runtimeType) {
	return false;
	}
	return other is FrameData
	&& other.size == size
	&& const ListEquality<SvgPath>().equals(other.paths, paths);
	}

	@override
	int get hashCode => Object.hash(size, Object.hashAll(paths));

	@override
	String toString() {
	return 'FrameData(size: $size, paths: $paths)';
	}
	}

	/// Represents an SVG path element.
	@immutable
	class SvgPath {
	const SvgPath(this.id, this.commands, {this.opacity = 1.0});

	final String id;
	final List<SvgPathCommand> commands;
	final double opacity;

	static const String _pathCommandAtom = r' ([a-zA-Z]) ([\-\.0-9 ,]*)';
	static final RegExp _pathCommandValidator = RegExp('^($_pathCommandAtom)*\$');
	static final RegExp _pathCommandMatcher = RegExp(_pathCommandAtom);

	static SvgPath fromElement(XmlElement pathElement) {
	assert(pathElement.name.local == 'path');
	final String id = _extractAttr(pathElement, 'id');
	final String dAttr = _extractAttr(pathElement, 'd');
	final List<SvgPathCommand> commands = <SvgPathCommand>[];
	final SvgPathCommandBuilder commandsBuilder = SvgPathCommandBuilder();
	if (!_pathCommandValidator.hasMatch(dAttr)) {
	throw Exception('illegal or unsupported path d expression: $dAttr');
	}
	for (final Match match in _pathCommandMatcher.allMatches(dAttr)) {
	final String commandType = match.group(1)!;
	final String pointStr = match.group(2)!;
	commands.add(commandsBuilder.build(commandType, parsePoints(pointStr)));
	}
	return SvgPath(id, commands);
	}

	SvgPath _applyTransform(_Transform transform) {
	final List<SvgPathCommand> transformedCommands =
	commands.map<SvgPathCommand>((SvgPathCommand c) => c._applyTransform(transform)).toList();
	return SvgPath(id, transformedCommands, opacity: opacity * transform.opacity);
	}

	@override
	bool operator ==(Object other) {
	if (other.runtimeType != runtimeType) {
	return false;
	}
	return other is SvgPath
	&& other.id == id
	&& other.opacity == opacity
	&& const ListEquality<SvgPathCommand>().equals(other.commands, commands);
	}

	@override
	int get hashCode => Object.hash(id, Object.hashAll(commands), opacity);

	@override
	String toString() {
	return 'SvgPath(id: $id, opacity: $opacity, commands: $commands)';
	}

	}

	/// Represents a single SVG path command from an SVG d element.
	///
	/// This class normalizes all the 'd' commands into a single type, that has
	/// a command type and a list of points.
	///
	/// Some examples of how d commands translated to SvgPathCommand:
	/// * "M 0.0, 1.0" => SvgPathCommand('M', [Point(0.0, 1.0)])
	/// * "Z" => SvgPathCommand('Z', [])
	/// * "C 1.0, 1.0 2.0, 2.0 3.0, 3.0" SvgPathCommand('C', [Point(1.0, 1.0),
	/// Point(2.0, 2.0), Point(3.0, 3.0)])
	@immutable
	class SvgPathCommand {
	const SvgPathCommand(this.type, this.points);

	/// The command type.
	final String type;

	/// List of points used by this command.
	final List<Point<double>> points;

	SvgPathCommand _applyTransform(_Transform transform) {
	final List<Point<double>> transformedPoints =
	_vector3ArrayToPoints(
	transform.transformMatrix.applyToVector3Array(
	_pointsToVector3Array(points)
	)
	);
	return SvgPathCommand(type, transformedPoints);
	}

	@override
	bool operator ==(Object other) {
	if (other.runtimeType != runtimeType) {
	return false;
	}
	return other is SvgPathCommand
	&& other.type == type
	&& const ListEquality<Point<double>>().equals(other.points, points);
	}

	@override
	int get hashCode => Object.hash(type, Object.hashAll(points));

	@override
	String toString() {
	return 'SvgPathCommand(type: $type, points: $points)';
	}
	}

	class SvgPathCommandBuilder {
	static const Map<String, void> kRelativeCommands = <String, void> {
	'c': null,
	'l': null,
	'm': null,
	't': null,
	's': null,
	};

	Point<double> lastPoint = const Point<double>(0.0, 0.0);
	Point<double> subPathStartPoint = const Point<double>(0.0, 0.0);

	SvgPathCommand build(String type, List<Point<double>> points) {
	List<Point<double>> absPoints = points;
	if (_isRelativeCommand(type)) {
	absPoints = points.map<Point<double>>((Point<double> p) => p + lastPoint).toList();
	}

	if (type == 'M' \|\| type == 'm') {
	subPathStartPoint = absPoints.last;
	}

	if (type == 'Z' \|\| type == 'z') {
	lastPoint = subPathStartPoint;
	} else {
	lastPoint = absPoints.last;
	}

	return SvgPathCommand(type.toUpperCase(), absPoints);
	}

	static bool _isRelativeCommand(String type) {
	return kRelativeCommands.containsKey(type);
	}
	}

	List<double> _pointsToVector3Array(List<Point<double>> points) {
	final List<double> result = List<double>.filled(points.length * 3, 0.0);
	for (int i = 0; i < points.length; i += 1) {
	result[i * 3] = points[i].x;
	result[i * 3 + 1] = points[i].y;
	result[i * 3 + 2] = 1.0;
	}
	return result;
	}

	List<Point<double>> _vector3ArrayToPoints(List<double> vector) {
	final int numPoints = (vector.length / 3).floor();
	final List<Point<double>> points = <Point<double>>[
	for (int i = 0; i < numPoints; i += 1)
	Point<double>(vector[i3], vector[i3 + 1]),
	];
	return points;
	}

	/// Represents a transformation to apply on an SVG subtree.
	///
	/// This includes more transforms than the ones described by the SVG transform
	/// attribute, e.g opacity.
	class _Transform {

	/// Constructs a new _Transform, default arguments create a no-op transform.
	_Transform({Matrix3? transformMatrix, this.opacity = 1.0}) :
	transformMatrix = transformMatrix ?? Matrix3.identity();

	final Matrix3 transformMatrix;
	final double opacity;

	_Transform applyTransform(_Transform transform) {
	return _Transform(
	transformMatrix: transform.transformMatrix.multiplied(transformMatrix),
	opacity: transform.opacity * opacity,
	);
	}
	}


	const String _transformCommandAtom = r' ([^(]+)\(([^)])\)';
	final RegExp _transformValidator = RegExp('^($_transformCommandAtom)*\$');
	final RegExp _transformCommand = RegExp(_transformCommandAtom);

	Matrix3 _parseSvgTransform(String transform) {
	if (!_transformValidator.hasMatch(transform)) {
	throw Exception('illegal or unsupported transform: $transform');
	}
	final Iterable<Match> matches =_transformCommand.allMatches(transform).toList().reversed;
	Matrix3 result = Matrix3.identity();
	for (final Match m in matches) {
	final String command = m.group(1)!;
	final String params = m.group(2)!;
	if (command == 'translate') {
	result = _parseSvgTranslate(params).multiplied(result);
	continue;
	}
	if (command == 'scale') {
	result = _parseSvgScale(params).multiplied(result);
	continue;
	}
	if (command == 'rotate') {
	result = _parseSvgRotate(params).multiplied(result);
	continue;
	}
	throw Exception('unimplemented transform: $command');
	}
	return result;
	}

	final RegExp _valueSeparator = RegExp('( , \| +)');

	Matrix3 _parseSvgTranslate(String paramsStr) {
	final List<String> params = paramsStr.split(_valueSeparator);
	assert(params.isNotEmpty);
	assert(params.length <= 2);
	final double x = double.parse(params[0]);
	final double y = params.length < 2 ? 0 : double.parse(params[1]);
	return _matrix(1.0, 0.0, 0.0, 1.0, x, y);
	}

	Matrix3 _parseSvgScale(String paramsStr) {
	final List<String> params = paramsStr.split(_valueSeparator);
	assert(params.isNotEmpty);
	assert(params.length <= 2);
	final double x = double.parse(params[0]);
	final double y = params.length < 2 ? 0 : double.parse(params[1]);
	return _matrix(x, 0.0, 0.0, y, 0.0, 0.0);
	}

	Matrix3 _parseSvgRotate(String paramsStr) {
	final List<String> params = paramsStr.split(_valueSeparator);
	assert(params.length == 1);
	final double a = radians(double.parse(params[0]));
	return _matrix(cos(a), sin(a), -sin(a), cos(a), 0.0, 0.0);
	}

	Matrix3 _matrix(double a, double b, double c, double d, double e, double f) {
	return Matrix3(a, b, 0.0, c, d, 0.0, e, f, 1.0);
	}

	// Matches a pixels expression e.g "14px".
	// First group is just the number.
	final RegExp _pixelsExp = RegExp(r'^([0-9]+)px$');

	/// Parses a pixel expression, e.g "14px", and returns the number.
	/// Throws an [ArgumentError] if the given string doesn't match the pattern.
	int parsePixels(String pixels) {
	if (!_pixelsExp.hasMatch(pixels)) {
	throw ArgumentError(
	"illegal pixels expression: '$pixels'"
	' (the tool currently only support pixel units).');
	}
	return int.parse(_pixelsExp.firstMatch(pixels)!.group(1)!);
	}

	String _extractAttr(XmlElement element, String name) {
	try {
	return element.attributes.singleWhere((XmlAttribute x) => x.name.local == name)
	.value;
	} catch (e) {
	throw ArgumentError(
	"Can't find a single '$name' attributes in ${element.name}, "
	'attributes were: ${element.attributes}'
	);
	}
	}

	bool _hasAttr(XmlElement element, String name) {
	return element.attributes.where((XmlAttribute a) => a.name.local == name).isNotEmpty;
	}

	XmlElement _extractSvgElement(XmlDocument document) {
	return document.children.singleWhere(
	(XmlNode node) => node.nodeType == XmlNodeType.ELEMENT &&
	_asElement(node).name.local == 'svg'
	) as XmlElement;
	}

	XmlElement _asElement(XmlNode node) => node as XmlElement;