benchmarks/Utf8DecodeComplex/dart/benchmarks.dart - sdk - Git at Google

 // Copyright (c) 2023, 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.
 //

 /// Benchmark for UTF-8 decoding, complex cases.
 ///
 /// This benckmark complements the `Utf8Decode` benchmarks by exploring
 /// different scenarios. There are three axes of variation - input complexity,
 /// conversion type, and polymorphism. The variantions are represented in the
 /// benchmark name, roughly
 ///
 ///     Utf8DecodeComplex.<polymorphism>.<conversion>.<data>.<complexity>.10k
 ///
 /// ### Complexity
 ///
 /// The input complexity is explored by having input sequences that are the
 /// UTF-8 encoding of (1) ASCII strings ('ascii'), (2) strings that can be
 /// represented by one-byte strings ('1byte'), and (3) strings need to be
 /// represented by two-byte strings ('2byte').
 ///
 /// Both of of these benchmarks process 10k bytes of input:
 ///
 ///     Utf8DecodeComplex.mono.simple.ascii.10k
 ///     Utf8DecodeComplex.mono.simple.2byte.10k
 ///
 /// The first has ascii bytes as input, the simplest case. The second requires
 /// parsing the variable-length UTF-8 code points.
 ///
 /// ### Conversion
 ///
 /// The conversion variations are 'simple', for a one-shot conversion of a List
 /// of bytes to a string, and 'chunked' for a conversion that uses the chunked
 /// conversion API to process the 10k bytes in chunks of a few hundred
 /// bytes. This exercises different paths through the decoder. We would expect
 /// the chuncked version to be slower, but only by a few percent.
 ///
 /// ### Data
 ///
 /// The type of the input is part of the benchmark name. When the input is a
 /// modifiable `Unit8List`, there is no `.<data>` part to the name. Otherwise:
 ///
 ///     .list  - Input is a system List (`List.of`)
 ///     .unmodifiable - Input is an ummodifiable `Uint8List`.
 ///
 /// ### Polymorphism
 ///
 /// Polymorphism is explored by compiling several programs that run different
 /// subsets of the benchmarks.
 ///
 /// Whole-program optimizing compilers like AOT or dart2js can sometimes 'see'
 /// that the conversion code is called with a single implementation of List and
 /// optimize the code accordingly. This can produce faster code, but might be
 /// too optimistic as prediction of real-world performance.
 ///
 /// These two benchmarks run the same code, on a `Uint8List` containing the same
 /// values. Other than the name, the benchmarks are identical:
 ///
 ///     Utf8DecodeComplex.mono.simple.ascii.10k
 ///     Utf8DecodeComplex.poly.simple.ascii.10k
 ///
 /// The difference is that the 'mono' benchmark is part of a program that passes
 /// only modifiable `Uint8List` lists to `utf8.decode`, whereas the 'poly'
 /// benchmark is part of a program that passes several different List
 /// implementation type to `utf8.decode`, including system lists (`List.of`) and
 /// and unmodifiable Uint8Lists.
 ///
 /// There are three monomorphic entry points which are called from the `main`
 /// method of an otherwise trivial program - `mainMono1`, `mainMono2` and
 /// `mainMono3`.  `mainMono1` does conversions exclusively on the preferred data
 /// type, `Uint8List`.  `mainMono2` does conversions exclusively on the system
 /// list type (`List.of`). `mainMono3` does conversions exclusively on
 /// unmodifiable `Uint8List`.
 ///
 /// The primary program calls the `mainPoly` entry point.
 ///
 /// Benchmark results from the different programs can be collected into a single
 /// suite.
 library;

 import 'dart:convert';
 import 'dart:math' show min;
 import 'dart:typed_data';

 import 'package:benchmark_harness/benchmark_harness.dart';
 import 'package:expect/expect.dart';

 // ASCII values which are start the sequence for quick validation that
 // conversion happened.
 const bytes0tag = 0x30;
 const bytes1tag = 0x31;
 const bytes2tag = 0x32;

 // Input which decodes to a string where all code units are 7-bit ASCII.
 const bytes0 = [
   bytes0tag, //    0, U+0030
   0x48, 0x45, 0x4C, 0x4C, 0x4f, 0x0A, // "HELLO\n"
 ];

 // Input which decodes to a string where all code units fit in 1 byte.
 const bytes1 = [
   bytes1tag, //    1, U+0031
   0x41, //         A, U+0040
   0xC2, 0xB1, //   ±, U+00B1
   0xC3, 0xB7, //   ÷, U+00F7
   0x0A, //         \n, U+000A
 ];

 // Input which decodes to a string where some code units require 2 bytes.
 const bytes2 = [
   bytes2tag, //              2, U+0032
   0x41, //                   A, U+0040
   0xC2, 0xB1, //             ±, U+00B1
   0xC3, 0xB7, //             ÷, U+00F7
   0xC4, 0x90, //             Đ, U+0111
   0xE0, 0xA6, 0x86, //       আ, U+0986
   0xF0, 0x9F, 0x87, 0xB9, // 🇹, U+1F1F9
   0xF0, 0x9F, 0x87, 0xBB, // 🇻, U+1F1FB  🇹🇻
 ];

 const targetSize = 10000;
 const chunkSize = 250;

 void check(String result, List<int> sequence) {
   // Each sequence starts with a different ASCII value so we can quickly 'look
   // up' the expected length of the decoded expanded sequence.
   final expectedLength = switch (sequence[0]) {
     bytes0tag => targetSize,
     bytes1tag => 7144,
     bytes2tag => 5266,
     _ => throw 'Unexpected sequence start: ${sequence[0]}'
   };
   Expect.equals(expectedLength, result.length);
 }

 /// Expands a sequence by repetition and padding to `targetSize` bytes.
 Uint8List makeSequence(List<int> bytes) {
   Expect.equals(
       1,
       bytes.length.gcd(chunkSize),
       'Bad repeated size (${bytes.length}).'
       ' Repeated sequence should be co-prime with chunk size ($chunkSize)'
       ' to exercise more UTF-8 boundaries');
   final repeats =
       List.filled(targetSize ~/ bytes.length, bytes).expand((byte) => byte);
   final padding = List.filled(targetSize.remainder(bytes.length), 0); // NULs.
   final sequence = Uint8List.fromList([...repeats, ...padding]);
   Expect.equals(targetSize, sequence.length);
   return sequence;
 }

 final Uint8List sequence0 = makeSequence(bytes0);
 final Uint8List sequence1 = makeSequence(bytes1);
 final Uint8List sequence2 = makeSequence(bytes2);

 class Utf8DecodeBenchmarkBase extends BenchmarkBase {
   Utf8DecodeBenchmarkBase(String name) : super('Utf8DecodeComplex.$name');

   late int totalInputSize;

   @override
   void exercise() {
     // Only a single run per measurement instead of the usual 10.
     run();
   }

   @override
   double measure() {
     // Report time per input byte.
     return super.measure() / totalInputSize;
   }

   @override
   void report() {
     // Report time in nanoseconds.
     final double score = measure() * 1000.0;
     print('$name(RunTime): $score ns.');
   }
 }

 class Simple extends Utf8DecodeBenchmarkBase {
   final List<int> sequence;
   Simple(super.name, this.sequence) {
     totalInputSize = sequence.length;
   }

   @override
   void run() {
     final result = utf8.decode(sequence);
     check(result, sequence);
   }
 }

 abstract class ChunkedBase extends Utf8DecodeBenchmarkBase {
   final List<int> sequence;
   late List<List<int>> chunks;
   ChunkedBase(super.name, this.sequence);

   List<int> slice(List<int> list, int start, int end);

   @override
   void setup() {
     totalInputSize = sequence.length;
     chunks = [];
     for (int i = 0; i < totalInputSize; i += chunkSize) {
       final chunk = slice(sequence, i, min(i + chunkSize, totalInputSize));
       chunks.add(chunk);
     }
   }

   @override
   void run() {
     late final String result;
     final byteSink = const Utf8Decoder().startChunkedConversion(
         StringConversionSink.withCallback((s) => result = s));

     for (final chunk in chunks) {
       byteSink.add(chunk);
     }
     byteSink.close();
     check(result, sequence);
   }
 }

 class Chunked extends ChunkedBase {
   Chunked(super.name, super.sequence);

   @override
   List<int> slice(List<int> list, int start, int end) {
     return list.sublist(start, end);
   }
 }

 class ChunkedUnmodifiable extends ChunkedBase {
   ChunkedUnmodifiable(super.name, Uint8List super.sequence);

   @override
   Uint8List slice(List<int> list, int start, int end) {
     return Uint8List.fromList(list.sublist(start, end)).asUnmodifiableView();
   }
 }

 void runAll(List<BenchmarkBase> benchmarks) {
   // Warm up all the benchmarks to avoid overly optimistic results for the first
   // few benchmarks due to temporary monomorphism in JIT compilers.
   for (var bm in benchmarks) {
     bm.setup();
     bm.warmup();
   }

   for (var bm in benchmarks) {
     bm.report();
   }
 }

 void mainPoly() {
   // Polymorphic: Inputs of several types.
   final benchmarks = [
     Simple('poly.simple.ascii.10k', sequence0),
     Simple('poly.simple.1byte.10k', sequence1),
     Simple('poly.simple.2byte.10k', sequence2),
     Simple('poly.simple.list.ascii.10k', List.of(sequence0)),
     Simple('poly.simple.list.1byte.10k', List.of(sequence1)),
     Simple('poly.simple.list.2byte.10k', List.of(sequence2)),
     Simple(
         'poly.simple.unmodifiable.ascii.10k', sequence0.asUnmodifiableView()),
     Simple(
         'poly.simple.unmodifiable.1byte.10k', sequence1.asUnmodifiableView()),
     Simple(
         'poly.simple.unmodifiable.2byte.10k', sequence2.asUnmodifiableView()),
     Chunked('poly.chunked.ascii.10k', sequence0),
     Chunked('poly.chunked.1byte.10k', sequence1),
     Chunked('poly.chunked.2byte.10k', sequence2),
     Chunked('poly.chunked.list.ascii.10k', List.of(sequence0)),
     Chunked('poly.chunked.list.1byte.10k', List.of(sequence1)),
     Chunked('poly.chunked.list.2byte.10k', List.of(sequence2)),
     ChunkedUnmodifiable(
         'poly.chunked.unmodifiable.ascii.10k', sequence0.asUnmodifiableView()),
     ChunkedUnmodifiable(
         'poly.chunked.unmodifiable.1byte.10k', sequence1.asUnmodifiableView()),
     ChunkedUnmodifiable(
         'poly.chunked.unmodifiable.2byte.10k', sequence2.asUnmodifiableView()),
   ];
   runAll(benchmarks);
 }

 void mainMono1() {
   // Monomorphic: All inputs are `Uint8List`s.
   final benchmarks = [
     Simple('mono.simple.ascii.10k', sequence0),
     Simple('mono.simple.1byte.10k', sequence1),
     Simple('mono.simple.2byte.10k', sequence2),
     Chunked('mono.chunked.ascii.10k', sequence0),
     Chunked('mono.chunked.1byte.10k', sequence1),
     Chunked('mono.chunked.2byte.10k', sequence2),
   ];
   runAll(benchmarks);
 }

 void mainMono2() {
   // Monomorphic: All inputs are ordinary (system) Lists.
   final benchmarks = [
     Simple('mono.simple.list.ascii.10k', List.of(sequence0)),
     Simple('mono.simple.list.1byte.10k', List.of(sequence1)),
     Simple('mono.simple.list.2byte.10k', List.of(sequence2)),
     Chunked('mono.chunked.list.ascii.10k', List.of(sequence0)),
     Chunked('mono.chunked.list.1byte.10k', List.of(sequence1)),
     Chunked('mono.chunked.list.2byte.10k', List.of(sequence2)),
   ];
   runAll(benchmarks);
 }

 void mainMono3() {
   // Monomorphic: All inputs are unmodifiable `Uint8List`s.
   final benchmarks = [
     Simple(
         'mono.simple.unmodifiable.ascii.10k', sequence0.asUnmodifiableView()),
     Simple(
         'mono.simple.unmodifiable.1byte.10k', sequence1.asUnmodifiableView()),
     Simple(
         'mono.simple.unmodifiable.2byte.10k', sequence2.asUnmodifiableView()),
     ChunkedUnmodifiable(
         'mono.chunked.unmodifiable.ascii.10k', sequence0.asUnmodifiableView()),
     ChunkedUnmodifiable(
         'mono.chunked.unmodifiable.1byte.10k', sequence1.asUnmodifiableView()),
     ChunkedUnmodifiable(
         'mono.chunked.unmodifiable.2byte.10k', sequence2.asUnmodifiableView()),
   ];
   runAll(benchmarks);
 }
	// Copyright (c) 2023, 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.
	//

	/// Benchmark for UTF-8 decoding, complex cases.
	///
	/// This benckmark complements the `Utf8Decode` benchmarks by exploring
	/// different scenarios. There are three axes of variation - input complexity,
	/// conversion type, and polymorphism. The variantions are represented in the
	/// benchmark name, roughly
	///
	/// Utf8DecodeComplex.<polymorphism>.<conversion>.<data>.<complexity>.10k
	///
	/// ### Complexity
	///
	/// The input complexity is explored by having input sequences that are the
	/// UTF-8 encoding of (1) ASCII strings ('ascii'), (2) strings that can be
	/// represented by one-byte strings ('1byte'), and (3) strings need to be
	/// represented by two-byte strings ('2byte').
	///
	/// Both of of these benchmarks process 10k bytes of input:
	///
	/// Utf8DecodeComplex.mono.simple.ascii.10k
	/// Utf8DecodeComplex.mono.simple.2byte.10k
	///
	/// The first has ascii bytes as input, the simplest case. The second requires
	/// parsing the variable-length UTF-8 code points.
	///
	/// ### Conversion
	///
	/// The conversion variations are 'simple', for a one-shot conversion of a List
	/// of bytes to a string, and 'chunked' for a conversion that uses the chunked
	/// conversion API to process the 10k bytes in chunks of a few hundred
	/// bytes. This exercises different paths through the decoder. We would expect
	/// the chuncked version to be slower, but only by a few percent.
	///
	/// ### Data
	///
	/// The type of the input is part of the benchmark name. When the input is a
	/// modifiable `Unit8List`, there is no `.<data>` part to the name. Otherwise:
	///
	/// .list - Input is a system List (`List.of`)
	/// .unmodifiable - Input is an ummodifiable `Uint8List`.
	///
	/// ### Polymorphism
	///
	/// Polymorphism is explored by compiling several programs that run different
	/// subsets of the benchmarks.
	///
	/// Whole-program optimizing compilers like AOT or dart2js can sometimes 'see'
	/// that the conversion code is called with a single implementation of List and
	/// optimize the code accordingly. This can produce faster code, but might be
	/// too optimistic as prediction of real-world performance.
	///
	/// These two benchmarks run the same code, on a `Uint8List` containing the same
	/// values. Other than the name, the benchmarks are identical:
	///
	/// Utf8DecodeComplex.mono.simple.ascii.10k
	/// Utf8DecodeComplex.poly.simple.ascii.10k
	///
	/// The difference is that the 'mono' benchmark is part of a program that passes
	/// only modifiable `Uint8List` lists to `utf8.decode`, whereas the 'poly'
	/// benchmark is part of a program that passes several different List
	/// implementation type to `utf8.decode`, including system lists (`List.of`) and
	/// and unmodifiable Uint8Lists.
	///
	/// There are three monomorphic entry points which are called from the `main`
	/// method of an otherwise trivial program - `mainMono1`, `mainMono2` and
	/// `mainMono3`. `mainMono1` does conversions exclusively on the preferred data
	/// type, `Uint8List`. `mainMono2` does conversions exclusively on the system
	/// list type (`List.of`). `mainMono3` does conversions exclusively on
	/// unmodifiable `Uint8List`.
	///
	/// The primary program calls the `mainPoly` entry point.
	///
	/// Benchmark results from the different programs can be collected into a single
	/// suite.
	library;

	import 'dart:convert';
	import 'dart:math' show min;
	import 'dart:typed_data';

	import 'package:benchmark_harness/benchmark_harness.dart';
	import 'package:expect/expect.dart';

	// ASCII values which are start the sequence for quick validation that
	// conversion happened.
	const bytes0tag = 0x30;
	const bytes1tag = 0x31;
	const bytes2tag = 0x32;

	// Input which decodes to a string where all code units are 7-bit ASCII.
	const bytes0 = [
	bytes0tag, // 0, U+0030
	0x48, 0x45, 0x4C, 0x4C, 0x4f, 0x0A, // "HELLO\n"
	];

	// Input which decodes to a string where all code units fit in 1 byte.
	const bytes1 = [
	bytes1tag, // 1, U+0031
	0x41, // A, U+0040
	0xC2, 0xB1, // ±, U+00B1
	0xC3, 0xB7, // ÷, U+00F7
	0x0A, // \n, U+000A
	];

	// Input which decodes to a string where some code units require 2 bytes.
	const bytes2 = [
	bytes2tag, // 2, U+0032
	0x41, // A, U+0040
	0xC2, 0xB1, // ±, U+00B1
	0xC3, 0xB7, // ÷, U+00F7
	0xC4, 0x90, // Đ, U+0111
	0xE0, 0xA6, 0x86, // আ, U+0986
	0xF0, 0x9F, 0x87, 0xB9, // 🇹, U+1F1F9
	0xF0, 0x9F, 0x87, 0xBB, // 🇻, U+1F1FB 🇹🇻
	];

	const targetSize = 10000;
	const chunkSize = 250;

	void check(String result, List<int> sequence) {
	// Each sequence starts with a different ASCII value so we can quickly 'look
	// up' the expected length of the decoded expanded sequence.
	final expectedLength = switch (sequence[0]) {
	bytes0tag => targetSize,
	bytes1tag => 7144,
	bytes2tag => 5266,
	_ => throw 'Unexpected sequence start: ${sequence[0]}'
	};
	Expect.equals(expectedLength, result.length);
	}

	/// Expands a sequence by repetition and padding to `targetSize` bytes.
	Uint8List makeSequence(List<int> bytes) {
	Expect.equals(
	1,
	bytes.length.gcd(chunkSize),
	'Bad repeated size (${bytes.length}).'
	' Repeated sequence should be co-prime with chunk size ($chunkSize)'
	' to exercise more UTF-8 boundaries');
	final repeats =
	List.filled(targetSize ~/ bytes.length, bytes).expand((byte) => byte);
	final padding = List.filled(targetSize.remainder(bytes.length), 0); // NULs.
	final sequence = Uint8List.fromList([...repeats, ...padding]);
	Expect.equals(targetSize, sequence.length);
	return sequence;
	}

	final Uint8List sequence0 = makeSequence(bytes0);
	final Uint8List sequence1 = makeSequence(bytes1);
	final Uint8List sequence2 = makeSequence(bytes2);

	class Utf8DecodeBenchmarkBase extends BenchmarkBase {
	Utf8DecodeBenchmarkBase(String name) : super('Utf8DecodeComplex.$name');

	late int totalInputSize;

	@override
	void exercise() {
	// Only a single run per measurement instead of the usual 10.
	run();
	}

	@override
	double measure() {
	// Report time per input byte.
	return super.measure() / totalInputSize;
	}

	@override
	void report() {
	// Report time in nanoseconds.
	final double score = measure() * 1000.0;
	print('$name(RunTime): $score ns.');
	}
	}

	class Simple extends Utf8DecodeBenchmarkBase {
	final List<int> sequence;
	Simple(super.name, this.sequence) {
	totalInputSize = sequence.length;
	}

	@override
	void run() {
	final result = utf8.decode(sequence);
	check(result, sequence);
	}
	}

	abstract class ChunkedBase extends Utf8DecodeBenchmarkBase {
	final List<int> sequence;
	late List<List<int>> chunks;
	ChunkedBase(super.name, this.sequence);

	List<int> slice(List<int> list, int start, int end);

	@override
	void setup() {
	totalInputSize = sequence.length;
	chunks = [];
	for (int i = 0; i < totalInputSize; i += chunkSize) {
	final chunk = slice(sequence, i, min(i + chunkSize, totalInputSize));
	chunks.add(chunk);
	}
	}

	@override
	void run() {
	late final String result;
	final byteSink = const Utf8Decoder().startChunkedConversion(
	StringConversionSink.withCallback((s) => result = s));

	for (final chunk in chunks) {
	byteSink.add(chunk);
	}
	byteSink.close();
	check(result, sequence);
	}
	}

	class Chunked extends ChunkedBase {
	Chunked(super.name, super.sequence);

	@override
	List<int> slice(List<int> list, int start, int end) {
	return list.sublist(start, end);
	}
	}

	class ChunkedUnmodifiable extends ChunkedBase {
	ChunkedUnmodifiable(super.name, Uint8List super.sequence);

	@override
	Uint8List slice(List<int> list, int start, int end) {
	return Uint8List.fromList(list.sublist(start, end)).asUnmodifiableView();
	}
	}

	void runAll(List<BenchmarkBase> benchmarks) {
	// Warm up all the benchmarks to avoid overly optimistic results for the first
	// few benchmarks due to temporary monomorphism in JIT compilers.
	for (var bm in benchmarks) {
	bm.setup();
	bm.warmup();
	}

	for (var bm in benchmarks) {
	bm.report();
	}
	}

	void mainPoly() {
	// Polymorphic: Inputs of several types.
	final benchmarks = [
	Simple('poly.simple.ascii.10k', sequence0),
	Simple('poly.simple.1byte.10k', sequence1),
	Simple('poly.simple.2byte.10k', sequence2),
	Simple('poly.simple.list.ascii.10k', List.of(sequence0)),
	Simple('poly.simple.list.1byte.10k', List.of(sequence1)),
	Simple('poly.simple.list.2byte.10k', List.of(sequence2)),
	Simple(
	'poly.simple.unmodifiable.ascii.10k', sequence0.asUnmodifiableView()),
	Simple(
	'poly.simple.unmodifiable.1byte.10k', sequence1.asUnmodifiableView()),
	Simple(
	'poly.simple.unmodifiable.2byte.10k', sequence2.asUnmodifiableView()),
	Chunked('poly.chunked.ascii.10k', sequence0),
	Chunked('poly.chunked.1byte.10k', sequence1),
	Chunked('poly.chunked.2byte.10k', sequence2),
	Chunked('poly.chunked.list.ascii.10k', List.of(sequence0)),
	Chunked('poly.chunked.list.1byte.10k', List.of(sequence1)),
	Chunked('poly.chunked.list.2byte.10k', List.of(sequence2)),
	ChunkedUnmodifiable(
	'poly.chunked.unmodifiable.ascii.10k', sequence0.asUnmodifiableView()),
	ChunkedUnmodifiable(
	'poly.chunked.unmodifiable.1byte.10k', sequence1.asUnmodifiableView()),
	ChunkedUnmodifiable(
	'poly.chunked.unmodifiable.2byte.10k', sequence2.asUnmodifiableView()),
	];
	runAll(benchmarks);
	}

	void mainMono1() {
	// Monomorphic: All inputs are `Uint8List`s.
	final benchmarks = [
	Simple('mono.simple.ascii.10k', sequence0),
	Simple('mono.simple.1byte.10k', sequence1),
	Simple('mono.simple.2byte.10k', sequence2),
	Chunked('mono.chunked.ascii.10k', sequence0),
	Chunked('mono.chunked.1byte.10k', sequence1),
	Chunked('mono.chunked.2byte.10k', sequence2),
	];
	runAll(benchmarks);
	}

	void mainMono2() {
	// Monomorphic: All inputs are ordinary (system) Lists.
	final benchmarks = [
	Simple('mono.simple.list.ascii.10k', List.of(sequence0)),
	Simple('mono.simple.list.1byte.10k', List.of(sequence1)),
	Simple('mono.simple.list.2byte.10k', List.of(sequence2)),
	Chunked('mono.chunked.list.ascii.10k', List.of(sequence0)),
	Chunked('mono.chunked.list.1byte.10k', List.of(sequence1)),
	Chunked('mono.chunked.list.2byte.10k', List.of(sequence2)),
	];
	runAll(benchmarks);
	}

	void mainMono3() {
	// Monomorphic: All inputs are unmodifiable `Uint8List`s.
	final benchmarks = [
	Simple(
	'mono.simple.unmodifiable.ascii.10k', sequence0.asUnmodifiableView()),
	Simple(
	'mono.simple.unmodifiable.1byte.10k', sequence1.asUnmodifiableView()),
	Simple(
	'mono.simple.unmodifiable.2byte.10k', sequence2.asUnmodifiableView()),
	ChunkedUnmodifiable(
	'mono.chunked.unmodifiable.ascii.10k', sequence0.asUnmodifiableView()),
	ChunkedUnmodifiable(
	'mono.chunked.unmodifiable.1byte.10k', sequence1.asUnmodifiableView()),
	ChunkedUnmodifiable(
	'mono.chunked.unmodifiable.2byte.10k', sequence2.asUnmodifiableView()),
	];
	runAll(benchmarks);
	}