benchmarks/MapCopy/dart/MapCopy.dart - sdk.git - Git at Google

 // Copyright (c) 2021, the Dart project authors.  Please see the AUTHORS file
 // for details. 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:collection';

 import 'package:benchmark_harness/benchmark_harness.dart';

 // Benchmark for polymorphic map copying.
 //
 // The set of benchmarks compares the cost of copying default Maps
 // (LinkedHashMaps) and HashMaps, for small and large maps.
 //
 // The maps have a key type `Object?`, since we want to use Strings, ints and
 // user-defined types.  The class `Thing` is a used-defined type with an
 // inexpensive hashCode operation. String keys are interesting because they are
 // quite common, and are special-cased in the JavaScript runtime.
 //
 // Benchmarks have names following this pattern:
 //
 //     MapCopy.{Map,HashMap}.{String,Thing}.of.{Map,HashMap}.{N}
 //     MapCopy.{Map,HashMap}.{String,Thing}.copyOf.{Map,HashMap}.{N}
 //     MapCopy.{Map,HashMap}.{String,Thing}.fromEntries.{Map,HashMap}.{N}
 //
 // For example, MapCopy.Map.String.of.HashMap.2 would call
 //
 //     Map<Object, Object>.of(m)
 //
 // where `m` is a `HashMap<String, Object>` with 2 entries.
 //
 // The `copyOf` variant creates an empty map and populates it using `forEach`,
 // so MapCopy.HashMap.Thing.copyOf.HashMap.100 would call:
 //
 //    HashMap<Object, Object> result = HashMap();
 //    m.forEach((key, value) { result[key] = value; });
 //
 // where `m` is a `HashMap<Thing, Object>` with 100 entries.
 //
 // The `fromEntries` variant creates a map via `Map.fromEntries(other.entries)`.
 //
 // Benchmarks are run for small maps (e.g. 2 entries, names ending in `.2`) and
 // 'large' maps (100 entries or `.100`). The benchmarks are normalized on the
 // number of elements to make benchmarks with different input sizes more
 // comparable.

 abstract class Benchmark<K> extends BenchmarkBase {
   final String targetKind; // 'Map' or 'HashMap'.
   late final String keyKind = _keyKind(K); // 'String' or 'Thing' or 'int'.
   final String methodKind; // 'of' or 'copyOf' or 'fromEntries'.
   final String sourceKind; // 'Map' or 'HashMap'.
   final int length;
   final List<Map<Object?, Object>> inputs = [];

   Benchmark(this.targetKind, this.methodKind, this.sourceKind, this.length)
       : super('MapCopy.$targetKind.${_keyKind(K)}.$methodKind.$sourceKind'
             '.$length');

   static String _keyKind(Type type) {
     if (type == String) return 'String';
     if (type == int) return 'int';
     if (type == Thing) return 'Thing';
     throw UnsupportedError('Unsupported type $type');
   }

   /// Override this method with one that will copy [input] to [output].
   void copy();

   @override
   void setup() {
     // Ensure setup() is idempotent.
     if (inputs.isNotEmpty) return;

     const totalEntries = 1000;

     int totalLength = 0;
     while (totalLength < totalEntries) {
       final sample = makeSample();
       inputs.add(sample);
       totalLength += sample.length;
     }

     // Sanity checks.
     for (var sample in inputs) {
       if (sample.length != length) throw 'Wrong length: $length $sample';
     }
     if (totalLength != totalEntries) {
       throw 'totalLength $totalLength != expected $totalEntries';
     }
   }

   int _sequence = 0;

   Map<Object?, Object> makeSample() {
     late final Map<K, Object> sample;
     if (sourceKind == 'Map') sample = {};
     if (sourceKind == 'HashMap') sample = HashMap();
     for (int i = 1; i <= length; i++) {
       _sequence = (_sequence + 119) & 0x1ffffff;
       final K key = makeKey(_sequence);
       sample[key] = i;
     }
     return sample;
   }

   K makeKey(int i) {
     if (keyKind == 'String') return 'key-$i' as K;
     if (keyKind == 'int') return i as K;
     if (keyKind == 'Thing') return Thing() as K;
     throw UnsupportedError('Unsupported type $K');
   }

   @override
   void run() {
     for (var sample in inputs) {
       input = sample;
       copy();
     }
     if (output.length != inputs.first.length) throw 'Bad result: $output';
   }
 }

 class Thing {
   static int _counter = 0;
   final int _index;
   Thing() : _index = ++_counter;

   @override
   bool operator ==(Object other) => other is Thing && _index == other._index;

   @override
   int get hashCode => _index;
 }

 // All the 'copy' methods use [input] and [output] rather than a parameter and
 // return value to avoid the possibility of a parametric covariance type check
 // in the call sequence.
 Map<Object?, Object> input = {};
 var output;

 class BaselineBenchmark extends Benchmark<String> {
   BaselineBenchmark(int length) : super('Map', 'baseline', 'Map', length);

   @override
   void copy() {
     // Dummy 'copy' to measure overhead of benchmarking loops.
     output = input;
   }
 }

 class MapOfBenchmark<K> extends Benchmark<K> {
   MapOfBenchmark(String sourceKind, int length)
       : super('Map', 'of', sourceKind, length);

   @override
   void copy() {
     output = Map<Object?, Object>.of(input);
   }
 }

 class HashMapOfBenchmark<K> extends Benchmark<K> {
   HashMapOfBenchmark(String sourceKind, int length)
       : super('HashMap', 'of', sourceKind, length);

   @override
   void copy() {
     output = HashMap<Object?, Object>.of(input);
   }
 }

 class MapCopyOfBenchmark<K> extends Benchmark<K> {
   MapCopyOfBenchmark(String sourceKind, int length)
       : super('Map', 'copyOf', sourceKind, length);

   @override
   void copy() {
     final map = <Object?, Object>{};
     input.forEach((k, v) {
       map[k] = v;
     });
     output = map;
   }
 }

 class HashMapCopyOfBenchmark<K> extends Benchmark<K> {
   HashMapCopyOfBenchmark(String sourceKind, int length)
       : super('HashMap', 'copyOf', sourceKind, length);

   @override
   void copy() {
     final map = HashMap<Object?, Object>();
     input.forEach((k, v) {
       map[k] = v;
     });
     output = map;
   }
 }

 class MapFromEntriesBenchmark<K> extends Benchmark<K> {
   MapFromEntriesBenchmark(String sourceKind, int length)
       : super('Map', 'fromEntries', sourceKind, length);

   @override
   void copy() {
     output = Map<Object?, Object>.fromEntries(input.entries);
   }
 }

 class HashMapFromEntriesBenchmark<K> extends Benchmark<K> {
   HashMapFromEntriesBenchmark(String sourceKind, int length)
       : super('HashMap', 'fromEntries', sourceKind, length);

   @override
   void copy() {
     output = HashMap<Object?, Object>.fromEntries(input.entries);
   }
 }

 /// Use the common methods for many different kinds of Map to make the calls in
 /// the runtime implementation polymorphic.
 void pollute() {
   final Map<String, Object> m1 = Map.of({'hello': 66});
   final Map<String, Object> m2 = HashMap.of(m1);
   final Map<int, Object> m3 = Map.of({1: 66});
   final Map<int, Object> m4 = HashMap.of({1: 66});
   final Map<Object, Object> m5 = Map.identity()
     ..[Thing()] = 1
     ..[Thing()] = 2;
   final Map<Object, Object> m6 = HashMap.identity()
     ..[Thing()] = 1
     ..[Thing()] = 2;
   final Map<Object, Object> m7 = UnmodifiableMapView(m1);
   final Map<Object, Object> m8 = UnmodifiableMapView(m2);
   final Map<Object, Object> m9 = UnmodifiableMapView(m3);
   final Map<Object, Object> m10 = UnmodifiableMapView(m4);

   int c = 0;
   for (final m in [m1, m2, m3, m4, m5, m6, m7, m8, m9, m10]) {
     final Map<Object, Object> d1 = Map.of(m);
     final Map<Object, Object> d2 = HashMap.of(m);
     // ignore: prefer_collection_literals
     final Map<Object, Object> d3 = Map()..addAll(m);
     final Map<Object, Object> d4 = {...m, ...m};
     final Map<Object, Object> d5 = HashMap()..addAll(m);
     final Map<Object, Object> d6 = Map.identity()..addAll(m);
     final Map<Object, Object> d7 = HashMap.identity()..addAll(m);
     final Map<Object, Object> d8 = Map.fromEntries(m.entries);
     final Map<Object, Object> d9 = HashMap.fromEntries(m.entries);
     for (final z in [d1, d2, d3, d4, d5, d6, d7, d8, d9]) {
       z.forEach((k, v) {
         c++;
       });
     }
   }
   const totalElements = 108;
   if (c != totalElements) throw StateError('c: $c != $totalElements');
 }

 /// Command-line arguments:
 ///
 /// `--baseline`: Run additional benchmarks to measure the benchmarking loop
 /// component.
 ///
 /// `--cross`: Run additional benchmarks for copying between Map and
 /// HashMap.
 ///
 /// `--int`: Run additional benchmarks with `int` keys.
 ///
 /// `--1`: Run additional benchmarks for singleton maps.
 ///
 /// `--all`: Run all benchmark variants.
 void main(List<String> commandLineArguments) {
   final arguments = [...commandLineArguments];

   bool includeBaseline = false;
   final Set<String> kinds = {'same'};
   final Set<String> types = {'String', 'Thing'};
   final Set<int> sizes = {2, 100};

   if (arguments.remove('--reset')) {
     kinds.clear();
     types.clear();
     sizes.clear();
   }

   if (arguments.remove('--baseline')) includeBaseline = true;
   if (arguments.remove('--cross')) kinds.add('cross');

   if (arguments.remove('--string')) types.add('String');
   if (arguments.remove('--thing')) types.add('Thing');
   if (arguments.remove('--int')) types.add('int');

   if (arguments.remove('--1')) sizes.add(1);
   if (arguments.remove('--2')) sizes.add(2);
   if (arguments.remove('--100')) sizes.add(100);

   if (arguments.remove('--all')) {
     kinds.addAll(['baseline', 'same', 'cross']);
     types.addAll(['String', 'Thing', 'int']);
     sizes.addAll([1, 2, 100]);
   }

   if (arguments.isNotEmpty) {
     throw ArgumentError('Unused command line arguments: $arguments');
   }

   if (kinds.isEmpty) kinds.add('same');
   if (types.isEmpty) types.add('String');
   if (sizes.isEmpty) sizes.add(2);

   List<Benchmark> makeBenchmarks<K>(int length) {
     return [
       // Map from Map
       if (kinds.contains('same')) ...[
         MapOfBenchmark<K>('Map', length),
         MapCopyOfBenchmark<K>('Map', length),
         MapFromEntriesBenchmark<K>('Map', length),
       ],
       // Map from HashMap
       if (kinds.contains('cross')) ...[
         MapOfBenchmark<K>('HashMap', length),
         MapCopyOfBenchmark<K>('HashMap', length),
         MapFromEntriesBenchmark<K>('HashMap', length),
       ],
       // HashMap from HashMap
       if (kinds.contains('same')) ...[
         HashMapOfBenchmark<K>('HashMap', length),
         HashMapCopyOfBenchmark<K>('HashMap', length),
         HashMapFromEntriesBenchmark<K>('HashMap', length),
       ],
       // HashMap from Map
       if (kinds.contains('cross')) ...[
         HashMapOfBenchmark<K>('Map', length),
         HashMapCopyOfBenchmark<K>('Map', length),
         HashMapFromEntriesBenchmark<K>('Map', length),
       ],
     ];
   }

   List<Benchmark> makeBenchmarksForLength(int length) {
     return [
       if (includeBaseline) BaselineBenchmark(length),
       if (types.contains('String')) ...makeBenchmarks<String>(length),
       if (types.contains('Thing')) ...makeBenchmarks<Thing>(length),
       if (types.contains('int')) ...makeBenchmarks<int>(length),
     ];
   }

   final benchmarks = [
     for (final length in sizes) ...makeBenchmarksForLength(length),
   ];

   // Warmup all benchmarks to ensure JIT compilers see full polymorphism.
   for (var benchmark in benchmarks) {
     pollute();
     benchmark.setup();
   }

   for (var benchmark in benchmarks) {
     pollute();
     benchmark.warmup();
   }

   for (var benchmark in benchmarks) {
     // `report` calls `setup`, but `setup` is idempotent.
     benchmark.report();
   }
 }
	// Copyright (c) 2021, the Dart project authors. Please see the AUTHORS file
	// for details. 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:collection';

	import 'package:benchmark_harness/benchmark_harness.dart';

	// Benchmark for polymorphic map copying.
	//
	// The set of benchmarks compares the cost of copying default Maps
	// (LinkedHashMaps) and HashMaps, for small and large maps.
	//
	// The maps have a key type `Object?`, since we want to use Strings, ints and
	// user-defined types. The class `Thing` is a used-defined type with an
	// inexpensive hashCode operation. String keys are interesting because they are
	// quite common, and are special-cased in the JavaScript runtime.
	//
	// Benchmarks have names following this pattern:
	//
	// MapCopy.{Map,HashMap}.{String,Thing}.of.{Map,HashMap}.{N}
	// MapCopy.{Map,HashMap}.{String,Thing}.copyOf.{Map,HashMap}.{N}
	// MapCopy.{Map,HashMap}.{String,Thing}.fromEntries.{Map,HashMap}.{N}
	//
	// For example, MapCopy.Map.String.of.HashMap.2 would call
	//
	// Map<Object, Object>.of(m)
	//
	// where `m` is a `HashMap<String, Object>` with 2 entries.
	//
	// The `copyOf` variant creates an empty map and populates it using `forEach`,
	// so MapCopy.HashMap.Thing.copyOf.HashMap.100 would call:
	//
	// HashMap<Object, Object> result = HashMap();
	// m.forEach((key, value) { result[key] = value; });
	//
	// where `m` is a `HashMap<Thing, Object>` with 100 entries.
	//
	// The `fromEntries` variant creates a map via `Map.fromEntries(other.entries)`.
	//
	// Benchmarks are run for small maps (e.g. 2 entries, names ending in `.2`) and
	// 'large' maps (100 entries or `.100`). The benchmarks are normalized on the
	// number of elements to make benchmarks with different input sizes more
	// comparable.

	abstract class Benchmark<K> extends BenchmarkBase {
	final String targetKind; // 'Map' or 'HashMap'.
	late final String keyKind = _keyKind(K); // 'String' or 'Thing' or 'int'.
	final String methodKind; // 'of' or 'copyOf' or 'fromEntries'.
	final String sourceKind; // 'Map' or 'HashMap'.
	final int length;
	final List<Map<Object?, Object>> inputs = [];

	Benchmark(this.targetKind, this.methodKind, this.sourceKind, this.length)
	: super('MapCopy.$targetKind.${_keyKind(K)}.$methodKind.$sourceKind'
	'.$length');

	static String _keyKind(Type type) {
	if (type == String) return 'String';
	if (type == int) return 'int';
	if (type == Thing) return 'Thing';
	throw UnsupportedError('Unsupported type $type');
	}

	/// Override this method with one that will copy [input] to [output].
	void copy();

	@override
	void setup() {
	// Ensure setup() is idempotent.
	if (inputs.isNotEmpty) return;

	const totalEntries = 1000;

	int totalLength = 0;
	while (totalLength < totalEntries) {
	final sample = makeSample();
	inputs.add(sample);
	totalLength += sample.length;
	}

	// Sanity checks.
	for (var sample in inputs) {
	if (sample.length != length) throw 'Wrong length: $length $sample';
	}
	if (totalLength != totalEntries) {
	throw 'totalLength $totalLength != expected $totalEntries';
	}
	}

	int _sequence = 0;

	Map<Object?, Object> makeSample() {
	late final Map<K, Object> sample;
	if (sourceKind == 'Map') sample = {};
	if (sourceKind == 'HashMap') sample = HashMap();
	for (int i = 1; i <= length; i++) {
	_sequence = (_sequence + 119) & 0x1ffffff;
	final K key = makeKey(_sequence);
	sample[key] = i;
	}
	return sample;
	}

	K makeKey(int i) {
	if (keyKind == 'String') return 'key-$i' as K;
	if (keyKind == 'int') return i as K;
	if (keyKind == 'Thing') return Thing() as K;
	throw UnsupportedError('Unsupported type $K');
	}

	@override
	void run() {
	for (var sample in inputs) {
	input = sample;
	copy();
	}
	if (output.length != inputs.first.length) throw 'Bad result: $output';
	}
	}

	class Thing {
	static int _counter = 0;
	final int _index;
	Thing() : _index = ++_counter;

	@override
	bool operator ==(Object other) => other is Thing && _index == other._index;

	@override
	int get hashCode => _index;
	}

	// All the 'copy' methods use [input] and [output] rather than a parameter and
	// return value to avoid the possibility of a parametric covariance type check
	// in the call sequence.
	Map<Object?, Object> input = {};
	var output;

	class BaselineBenchmark extends Benchmark<String> {
	BaselineBenchmark(int length) : super('Map', 'baseline', 'Map', length);

	@override
	void copy() {
	// Dummy 'copy' to measure overhead of benchmarking loops.
	output = input;
	}
	}

	class MapOfBenchmark<K> extends Benchmark<K> {
	MapOfBenchmark(String sourceKind, int length)
	: super('Map', 'of', sourceKind, length);

	@override
	void copy() {
	output = Map<Object?, Object>.of(input);
	}
	}

	class HashMapOfBenchmark<K> extends Benchmark<K> {
	HashMapOfBenchmark(String sourceKind, int length)
	: super('HashMap', 'of', sourceKind, length);

	@override
	void copy() {
	output = HashMap<Object?, Object>.of(input);
	}
	}

	class MapCopyOfBenchmark<K> extends Benchmark<K> {
	MapCopyOfBenchmark(String sourceKind, int length)
	: super('Map', 'copyOf', sourceKind, length);

	@override
	void copy() {
	final map = <Object?, Object>{};
	input.forEach((k, v) {
	map[k] = v;
	});
	output = map;
	}
	}

	class HashMapCopyOfBenchmark<K> extends Benchmark<K> {
	HashMapCopyOfBenchmark(String sourceKind, int length)
	: super('HashMap', 'copyOf', sourceKind, length);

	@override
	void copy() {
	final map = HashMap<Object?, Object>();
	input.forEach((k, v) {
	map[k] = v;
	});
	output = map;
	}
	}

	class MapFromEntriesBenchmark<K> extends Benchmark<K> {
	MapFromEntriesBenchmark(String sourceKind, int length)
	: super('Map', 'fromEntries', sourceKind, length);

	@override
	void copy() {
	output = Map<Object?, Object>.fromEntries(input.entries);
	}
	}

	class HashMapFromEntriesBenchmark<K> extends Benchmark<K> {
	HashMapFromEntriesBenchmark(String sourceKind, int length)
	: super('HashMap', 'fromEntries', sourceKind, length);

	@override
	void copy() {
	output = HashMap<Object?, Object>.fromEntries(input.entries);
	}
	}

	/// Use the common methods for many different kinds of Map to make the calls in
	/// the runtime implementation polymorphic.
	void pollute() {
	final Map<String, Object> m1 = Map.of({'hello': 66});
	final Map<String, Object> m2 = HashMap.of(m1);
	final Map<int, Object> m3 = Map.of({1: 66});
	final Map<int, Object> m4 = HashMap.of({1: 66});
	final Map<Object, Object> m5 = Map.identity()
	..[Thing()] = 1
	..[Thing()] = 2;
	final Map<Object, Object> m6 = HashMap.identity()
	..[Thing()] = 1
	..[Thing()] = 2;
	final Map<Object, Object> m7 = UnmodifiableMapView(m1);
	final Map<Object, Object> m8 = UnmodifiableMapView(m2);
	final Map<Object, Object> m9 = UnmodifiableMapView(m3);
	final Map<Object, Object> m10 = UnmodifiableMapView(m4);

	int c = 0;
	for (final m in [m1, m2, m3, m4, m5, m6, m7, m8, m9, m10]) {
	final Map<Object, Object> d1 = Map.of(m);
	final Map<Object, Object> d2 = HashMap.of(m);
	// ignore: prefer_collection_literals
	final Map<Object, Object> d3 = Map()..addAll(m);
	final Map<Object, Object> d4 = {...m, ...m};
	final Map<Object, Object> d5 = HashMap()..addAll(m);
	final Map<Object, Object> d6 = Map.identity()..addAll(m);
	final Map<Object, Object> d7 = HashMap.identity()..addAll(m);
	final Map<Object, Object> d8 = Map.fromEntries(m.entries);
	final Map<Object, Object> d9 = HashMap.fromEntries(m.entries);
	for (final z in [d1, d2, d3, d4, d5, d6, d7, d8, d9]) {
	z.forEach((k, v) {
	c++;
	});
	}
	}
	const totalElements = 108;
	if (c != totalElements) throw StateError('c: $c != $totalElements');
	}

	/// Command-line arguments:
	///
	/// `--baseline`: Run additional benchmarks to measure the benchmarking loop
	/// component.
	///
	/// `--cross`: Run additional benchmarks for copying between Map and
	/// HashMap.
	///
	/// `--int`: Run additional benchmarks with `int` keys.
	///
	/// `--1`: Run additional benchmarks for singleton maps.
	///
	/// `--all`: Run all benchmark variants.
	void main(List<String> commandLineArguments) {
	final arguments = [...commandLineArguments];

	bool includeBaseline = false;
	final Set<String> kinds = {'same'};
	final Set<String> types = {'String', 'Thing'};
	final Set<int> sizes = {2, 100};

	if (arguments.remove('--reset')) {
	kinds.clear();
	types.clear();
	sizes.clear();
	}

	if (arguments.remove('--baseline')) includeBaseline = true;
	if (arguments.remove('--cross')) kinds.add('cross');

	if (arguments.remove('--string')) types.add('String');
	if (arguments.remove('--thing')) types.add('Thing');
	if (arguments.remove('--int')) types.add('int');

	if (arguments.remove('--1')) sizes.add(1);
	if (arguments.remove('--2')) sizes.add(2);
	if (arguments.remove('--100')) sizes.add(100);

	if (arguments.remove('--all')) {
	kinds.addAll(['baseline', 'same', 'cross']);
	types.addAll(['String', 'Thing', 'int']);
	sizes.addAll([1, 2, 100]);
	}

	if (arguments.isNotEmpty) {
	throw ArgumentError('Unused command line arguments: $arguments');
	}

	if (kinds.isEmpty) kinds.add('same');
	if (types.isEmpty) types.add('String');
	if (sizes.isEmpty) sizes.add(2);

	List<Benchmark> makeBenchmarks<K>(int length) {
	return [
	// Map from Map
	if (kinds.contains('same')) ...[
	MapOfBenchmark<K>('Map', length),
	MapCopyOfBenchmark<K>('Map', length),
	MapFromEntriesBenchmark<K>('Map', length),
	],
	// Map from HashMap
	if (kinds.contains('cross')) ...[
	MapOfBenchmark<K>('HashMap', length),
	MapCopyOfBenchmark<K>('HashMap', length),
	MapFromEntriesBenchmark<K>('HashMap', length),
	],
	// HashMap from HashMap
	if (kinds.contains('same')) ...[
	HashMapOfBenchmark<K>('HashMap', length),
	HashMapCopyOfBenchmark<K>('HashMap', length),
	HashMapFromEntriesBenchmark<K>('HashMap', length),
	],
	// HashMap from Map
	if (kinds.contains('cross')) ...[
	HashMapOfBenchmark<K>('Map', length),
	HashMapCopyOfBenchmark<K>('Map', length),
	HashMapFromEntriesBenchmark<K>('Map', length),
	],
	];
	}

	List<Benchmark> makeBenchmarksForLength(int length) {
	return [
	if (includeBaseline) BaselineBenchmark(length),
	if (types.contains('String')) ...makeBenchmarks<String>(length),
	if (types.contains('Thing')) ...makeBenchmarks<Thing>(length),
	if (types.contains('int')) ...makeBenchmarks<int>(length),
	];
	}

	final benchmarks = [
	for (final length in sizes) ...makeBenchmarksForLength(length),
	];

	// Warmup all benchmarks to ensure JIT compilers see full polymorphism.
	for (var benchmark in benchmarks) {
	pollute();
	benchmark.setup();
	}

	for (var benchmark in benchmarks) {
	pollute();
	benchmark.warmup();
	}

	for (var benchmark in benchmarks) {
	// `report` calls `setup`, but `setup` is idempotent.
	benchmark.report();
	}
	}