An Introduction to Functional Programming

1. An Introduction toFunctional Programming ICS535-101

2. Topics • Introduction • Mathematical Functions • Fundamentals of Functional Programming Languages • Applications of Functional Languages • Comparison of Functional and Imperative Languages • The First F P Language: LISP • COMMON LISP ICS535-101

3. Introduction • The design of the imperative languages is based directly on the von Neumann architecture • Efficiency is the primary concern, rather than the suitability of the language for software development • The design of the functional languages is based on mathematical functions • A solid theoretical basis that is also closer to the user, but relatively unconcerned with the architecture of the machines on which programs will run ICS535-101

4. Introduction (Contd.) What is the Functional Paradigm ? • Program viewed as a collection of functions. • Functional programming is a style of programming in which the basic method of computation is the application of functions to arguments; • A functional language is one that supports and encourages the functional style. • Functional languages try to model mathematical functions as much as possible. • There are no assignments; assignments are bad and therefore banned! • Emphasize on simple and clean semantics. • Example languages: Scheme, Miranda, Haskell, ML ICS535-101

5. Introduction (Contd.) The Functional Paradigm: Computational Foundation • FLs are based on a computation model called lambda calculus • The lambda calculus is a simple mathematical theory developed before the advent of digital computers • The lambda calculus was intended to be a foundation of mathematics in the 1930s • The lambda calculus has very few syntactic constructs but it is Turing complete • It can compute any function that can be computed by a computing device • FLs are often considered as sugared versions of the lambda calculus ICS535-101

6. Introduction (Contd.) Functional Languages: Key Features • High-level of abstraction • Functional languages are among the highest-level languages in present-day use • Clean and simple semantics • Easier to reason about functional programs than imperative programs • Expressivity • Support for rapid application development • Support for concurrency • High orthogonality • Few language constructs compared to imperative or OO languages • Lazy evaluation (for some of them) ICS535-101

7. Mathematical Functions • Def: A mathematical function is a mapping of members of one set, called the domain set, to another set, called the range set • A lambda expression specifies the parameter(s) and the mapping of a function in the following form (x) x * x * x for the nameless function f(x) = x * x * x ICS535-101

8. Mathematical Functions (Contd.) • Lambda expressions describe nameless functions • Lambda expressions are applied to parameter(s) by placing the parameter(s) after the expression e.g. ((x) x * x * x)(3) which evaluates to 27 ICS535-101

9. Mathematical Functions (Contd.) • Def: A higher-order function, or functional form, is one that either takes functions as parameters or yields a function as its result, or both • Many kinds of functional forms, here are some: 1. Function Composition • A functional form that takes two functions as parameters and yields a function whose value is the first actual parameter function applied to the result of the second Form: h  f ° g which means h (x) f ( g ( x)) For f (x)  x * x * x and g (x)  x + 3, h  f ° g → h(x) = f(g(x)) = g(x) * g(x) * g(x) =(x + 3)* (x + 3)* (x + 3) ICS535-101

10. Mathematical Functions (Contd.) 2. Construction • A functional form that takes a list of functions as parameters and yields a list of the results of applying each of its parameter functions to a given parameter Form: [f, g] For f (x)  x * x * x and g (x)  x + 3, [f, g] (4) yields (64, 7) ICS535-101

11. Mathematical Functions (Contd.) 3. Apply-to-all • A functional form that takes a single function as a parameter and yields a list of values obtained by applying the given function to each element of a list of parameters Form:  For h (x)  x * x * x ( h, (3, 2, 4)) yields (27, 8, 64) ICS535-101

12. Why Functional Languages? The main reason we use functional programming is to reduce the time it takes to bring a product to the market and to reduce the total effort required to design and maintain our products. As functional programs are both shorter and more succinct than corresponding programs in languages such as C, C++, or Java, the number of errors made in the design is also greatly reduced • Ericsson Telecom • Widely used for teaching introductory computer science courses in European universities. ICS535-101

13. Applications of Functional Languages • APL is used for throw-away programs • LISP is used for artificial intelligence • Knowledge representation • Machine learning • Natural language processing • Modeling of speech and vision • Scheme is used to teach introductory programming at a significant number of universities ICS535-101

14. Comparing Fun. and Imp. Languages • Imperative Languages: • Efficient execution • Complex semantics • Complex syntax • Concurrency is programmer designed • Functional Languages: • Inefficient execution • Simple semantics • Simple syntax • Programs can automatically be made concurrent ICS535-101

15. The First F P Language: LISP • Data object types: originally only atoms and lists • List form: parenthesized collections of sublists and/or atoms e.g., (A B (C D) E) • Originally, LISP was a typeless language • LISP lists are stored internally as single-linked lists • Lambda notation is used to specify functions and function definitions. Function applications and data have the same form. e.g., If the list (A B C) is interpreted as data it isa simple list of threeatoms, A, B, and C. If it is interpreted as a functionapplication, it means that the function named A is applied to the two parameters, B and C • The first LISP interpreter appeared only as a demonstration of the universality of the computational capabilities of the notation ICS535-101

16. COMMON LISP • A combination of many of the features of the popular dialects of LISP around in the early 1980s • A large and complex language--the opposite of Scheme • Includes: • records • arrays • complex numbers • character strings • powerful I/O capabilities • packages with access control • imperative features like those of Scheme • iterative control statements ICS535-101