Computer Laboratory – Course pages 2014–15: Concepts in Programming Languages Skip to content | Access key help Search Advanced search A–Z Contact us Computer Laboratory Computer Laboratory Teaching Courses 2014–15 Concepts in Programming Languages Computer Design Computer Graphics and Image Processing Computer Networking Concurrent and Distributed Systems ECAD and Architecture Practical Classes Further Java Mathematical Methods for Computer Science Programming in C and C++ Prolog Semantics of Programming Languages Software Engineering Unix Tools Compiler Construction Computation Theory Databases Logic and Proof Artificial Intelligence I Complexity Theory Concepts in Programming Languages Economics, Law and Ethics Security I Course pages 2014–15 Concepts in Programming Languages Syllabus Course materials Information for supervisors Principal lecturer: Prof Alan Mycroft Taken by: Part IB Past exam questions Information for supervisors (contact lecturer for access permission) No. of lectures: 8 Suggested hours of supervisions: 2 Prerequisite courses: None. Aims The general aim of this course is to provide an overview of the basic concepts that appear in modern programming languages, the principles that underlie the design of programming languages, and their interaction. Lectures Introduction, motivation, and overview. What is a programming language? Application domains in language design. Program execution models. Theoretical foundations. Language standardization. History. The ancestors: Fortran, Lisp, Algol and Pascal. Key ideas: procedural (Fortran), declarative (Lisp), block structured (Algol and Pascal). Execution models (abstract machines), data types, control structures, storage, arrays and pointers, procedures and parameter passing, scope, strict and lazy evaluation, garbage collection. Programs as data (Lisp). [2 lectures] Object-oriented languages -- Concepts and origins: Simula (1964-67) and Smalltalk (1971-80). Dynamic lookup. Abstraction. Subtyping. Inheritance. Object models. Languages for parallel processing. Shared-memory concurrency with spawn/sync (OpenMP, Cilk, X10). Distributed-memory models (the actor model, Erlang). Types. Types in programming languages. Type systems. Type safety. Type checking and type inference. Polymorphism. Overloading. Type equivalence. Data abstraction and modularity: SML Modules (1984-97). Information hiding. Modularity. Signatures, structures, and functors. Sharing. Scala: a principled feature-rich language. Procedural and declarative aspects. Blocks and functions. Classes and objects. Generic types and methods. Variance annotations. Mixin-class composition. Objectives At the end of the course students should be familiar with several language paradigms and how they relate to different application domains; understand the design space of programming languages, including concepts and constructs from past languages as well as those that may be used in the future; develop a critical understanding of the programming languages that we use by being able to identify and compare the same concept as it appears in different languages. Recommended reading Books: * Mitchell, J.C. (2003). Concepts in programming languages. Cambridge University Press. * Scott, M.L. (2009). Programming language pragmatics. Morgan Kaufmann. Odersky, M. (2008). Scala by example. Programming Methods Laboratory, EPFL. Pratt, T.W. & Zelkowitz, M.V. (2001). Programming languages: design and implementation. Prentice Hall. Papers: Kay, A.C. (1993). The early history of Smalltalk. ACM SIGPLAN Notices, Vol. 28, No. 3. Kernighan, B. (1981). Why Pascal is not my favorite programming language. AT&T Bell Laboratories. Computing Science Technical Report No. 100. Koenig, A. (1994). An anecdote about ML type inference. USENIX Symposium on Very High Level Languages. Landin, P.J. (1966). The next 700 programming languages. Communications of the ACM, Vol. 9, Issue 3. Odersky, M. et al. (2006). An overview of the Scala programming language. Technical Report LAMP-REPORT-2006-001, Second Edition. McCarthy, J. (1960). Recursive functions of symbolic expressions and their computation by machine. Communications of the ACM, 3(4):184-195. Stroustrup, B. (1991). What is Object-Oriented Programming? (1991 revised version). Proceedings 1st European Software Festival. © 2015 Computer Laboratory, University of Cambridge Information provided by Prof Alan Mycroft