Michel Charpentier is an associate professor with the Computer Science department at the University of New Hampshire (UNH). His interests over the years have ranged from distributed systems to formal verification and mobile sensor networks. He has been with UNH since 1999 and currently teaches courses in programming languages, concurrency, formal verification, and model-checking.

Foreword by Cay Horstmann xxiii

Preface xxv

Acknowledgments xxxv

About the Author xxxvii

Part I. Functional Programming 1

Chapter 1: Concepts of Functional Programming 3

1.1 What Is Functional Programming? 3

1.2 Functions 4

1.3 From Functions to Functional Programming Concepts 6

1.4 Summary 7

Chapter 2: Functions in Programming Languages 9

2.1 Defining Functions 9

2.2 Composing Functions 10

2.3 Functions Defined as Methods 12

2.4 Operators Defined as Methods 12

2.5 Extension Methods 13

2.6 Local Functions 14

2.7 Repeated Arguments 15

2.8 Optional Arguments 16

2.9 Named Arguments 16

2.10 Type Parameters 17

2.11 Summary 19

Chapter 3: Immutability 21

3.1 Pure and Impure Functions 21

3.2 Actions 23

3.3 Expressions Versus Statements 25

3.4 Functional Variables 26

3.5 Immutable Objects 28

3.6 Implementation of Mutable State 29

3.7 Functional Lists 31

3.8 Hybrid Designs 32

3.9 Updating Collections of Mutable/Immutable Objects 35

3.10 Summary 36

Chapter 4: Case Study: ActivePassive Sets 39

4.1 Object-Oriented Design 39

4.2 Functional Values 41

4.3 Functional Objects 43

4.4 Summary 44

Chapter 5: Pattern Matching and Algebraic Data Types 47

5.1 Functional Switch 47

5.2 Tuples 48

5.3 Options 50

5.4 Revisiting Functional Lists 51

5.5 Trees 53

5.6 Illustration: List Zipper 56

5.7 Extractors 59

5.8 Summary 60

Chapter 6: Recursive Programming 63

6.1 The Need for Recursion 63

6.2 Recursive Algorithms 65

6.3 Key Principles of Recursive Algorithms 67

6.4 Recursive Structures 69

6.5 Tail Recursion 71

6.6 Examples of Tail Recursive Functions 73

6.7 Summary 77

Chapter 7: Recursion on Lists 79

7.1 Recursive Algorithms as Equalities 79

7.2 Traversing Lists 80

7.3 Returning Lists 82

7.4 Building Lists from the Execution Stack 84

7.5 Recursion on Multiple/Nested Lists 85

7.6 Recursion on Sublists Other Than the Tail 88

7.7 Building Lists in Reverse Order 90

7.8 Illustration: Sorting 92

7.9 Building Lists Efficiently 94

7.10 Summary 96

Chapter 8: Case Study: Binary Search Trees 99

8.1 Binary Search Trees 99

8.2 Sets of Integers as Binary Search Trees 100

8.3 Implementation Without Rebalancing 102

8.4 Self-Balancing Trees 107

8.5 Summary 113

Chapter 9: Higher-Order Functions 115

9.1 Functions as Values 115

9.2 Currying 118

9.3 Function Literals 120

9.4 Functions Versus Methods 123

9.5 Single-Abstract-Method Interfaces 124

9.6 Partial Application 125

9.7 Closures 130

9.8 Inversion of Control 133

9.9 Summary 133

Chapter 10: Standard Higher-Order Functions 137

10.1 Functions with Predicate Arguments 137

10.2 map and foreach 140

10.3 atMap 141

10.4 fold and reduce 146

10.5 iterate, tabulate, and unfold 148

10.6 sortWith, sortBy, maxBy, and minBy 149

10.7 groupBy and groupMap 150

10.8 Implementing Standard Higher-Order Functions 152

10.9 foreach, map, atMap, and for-Comprehensions 152

10.10 Summary 155

Chapter 11: Case Study: File Systems as Trees 157

11.1 Design Overview 157

11.2 A Node-Searching Helper Function 158

11.3 String Representation 158

11.4 Building Trees 160

11.5 Querying 164

11.6 Navigation 168

11.7 Tree Zipper 169

11.8 Summary 172

Chapter 12: Lazy Evaluation 173

12.1 Delayed Evaluation of Arguments 173

12.2 By-Name Arguments 174

12.3 Control Abstraction 176

12.4 Internal Domain-Specifc Languages 179

12.5 Streams as Lazily Evaluated Lists 180

12.6 Streams as Pipelines 182

12.7 Streams as Infinite Data Structures 184

12.8 Iterators 184

12.9 Lists, Streams, Iterators, and Views 187

12.10 Delayed Evaluation of Fields and Local Variables 190

12.11 Illustration: Subset-Sum 191

12.12 Summary 193

Chapter 13: Handling Failures 195

13.1 Exceptions and Special Values 195

13.2 Using Option 197

13.3 Using Try 198

13.4 Using Either 199

13.5 Higher-Order Functions and Pipelines 201

13.6 Summary 204

Chapter 14: Case Study: Trampolines 205

14.1 Tail-Call Optimization 205

14.2 Trampolines for Tail-Calls 206

14.3 Tail-Call Optimization in Java 207

14.4 Dealing with Non-Tail-Calls 209

14.5 Summary 213

A Brief Interlude 215

Chapter 15: Types (and Related Concepts) 217

15.1 Typing Strategies 217

15.2 Types as Sets 222

15.3 Types as Services 223

15.4 Abstract Data Types 224

15.5 Type Inference 225

15.6 Subtypes 229

15.7 Polymorphism 232

15.8 Type Variance 235

15.9 Type Bounds 241

15.10 Type Classes 245

15.11 Summary 250

Part II. Concurrent Programming 253

Chapter 16: Concepts of Concurrent Programming 255

16.1 Non-sequential Programs 255

16.2 Concurrent Programming Concepts 258

16.3 Summary 259

Chapter 17: Threads and Nondeterminism 261

17.1 Threads of Execution 261

17.2 Creating Threads Using Lambda Expressions 263

17.3 Nondeterministic Behavior of Multithreaded Programs 263

17.4 Thread Termination 264

17.5 Testing and Debugging Multithreaded Programs 266

17.6 Summary 268

Chapter 18: Atomicity and Locking 271

18.1 Atomicity 271

18.2 Non-atomic Operations 273

18.3 Atomic Operations and Non-atomic Composition 274

18.4 Locking 278

18.5 Intrinsic Locks 279

18.6 Choosing Locking Targets 281

18.7 Summary 283

Chapter 19: Thread-Safe Objects 285

19.1 Immutable Objects 285

19.2 Encapsulating Synchronization Policies 286

19.3 Avoiding Reference Escape 288

19.4 Public and Private Locks 289

19.5 Leveraging Immutable Types 290

19.6 Thread-Safety 293

19.7 Summary 295

Chapter 20: Case Study: Thread-Safe Queue 297

20.1 Queues as Pairs of Lists 297

20.2 Single Public Lock Implementation 298

20.3 Single Private Lock Implementation 301

20.4 Applying Lock Splitting 303

20.5 Summary 305

Chapter 21: Thread Pools 307

21.1 Fire-and-Forget Asynchronous Execution 307

21.2 Illustration: Parallel Server 309

21.3 Different Types of Thread Pools 312

21.4 Parallel Collections 314

21.5 Summary 318

Chapter 22: Synchronization 321

22.1 Illustration of the Need for Synchronization 321

22.2 Synchronizers 324

22.3 Deadlocks 325

22.4 Debugging Deadlocks with Thread Dumps 328

22.5 The Java Memory Model 330

22.6 Summary 335

Chapter 23: Common Synchronizers 337

23.1 Locks 337

23.2 Latches and Barriers 339

23.3 Semaphores 341

23.4 Conditions 343

23.5 Blocking Queues 349

23.6 Summary 353

Chapter 24: Case Study: Parallel Execution 355

24.1 Sequential Reference Implementation 355

24.2 One New Thread per Task 356

24.3 Bounded Number of Threads 357

24.4 Dedicated Thread Pool 359

24.5 Shared Thread Pool 360

24.6 Bounded Thread Pool 361

24.7 Parallel Collections 362

24.8 Asynchronous Task Submission Using Conditions 362

24.9 Two-Semaphore Implementation 367

24.10 Summary 368

Chapter 25: Futures and Promises 369

25.1 Functional Tasks 369

25.2 Futures as Synchronizers 371

25.3 Timeouts, Failures, and Cancellation 374

25.4 Future Variants 375

25.5 Promises 375

25.6 Illustration: Thread-Safe Caching 377

25.7 Summary 379

Chapter 26: Functional-Concurrent Programming 381

26.1 Correctness and Performance Issues with Blocking 381

26.2 Callbacks 384

26.3 Higher-Order Functions on Futures 385

26.4 Function atMap on Futures 388

26.5 Illustration: Parallel Server Revisited 390

26.6 Functional-Concurrent Programming Patterns 393

26.7 Summary 397

Chapter 27: Minimizing Thread Blocking 399

27.1 Atomic Operations 399

27.2 Lock-Free Data Structures 402

27.3 Fork/Join Pools 405

27.4 Asynchronous Programming 406

27.5 Actors 407

27.6 Reactive Streams 411

27.7 Non-blocking Synchronization 412

27.8 Summary 414

Chapter 28: Case Study: Parallel Strategies 417

28.1 Problem Definition 417

28.2 Sequential Implementation with Timeout 419

28.3 Parallel Implementation Using invokeAny 420

28.4 Parallel Implementation Using CompletionService 421

28.5 Asynchronous Implementation with Scala Futures 422

28.6 Asynchronous...