|Paul N. Hilfinger|
|787 Soda Hall|
|Email: Hilfinger@cs.berkeley.edu, cs164@cs|
|Office Hours: M2-3, Th2-3 in 787 Soda|
|Office Hours: F1-2 in 751 Soda.|
|Office Hours: Tu12:30-1:30 in 611 Soda Hall|
CS164 is an introduction to the design of programming languages and the implementation of translators for them. In the process, we'll do some general exploration of programming language design and its implications for implementation, and look at a dialect of at least one particular language, which this semester is Python.
One goal of this course is to explore the structure of programming languages and to consider alternatives to familiar programming language features. We'll also study the problem of translating programming languages into machine-executable forms, using Python as a concrete example of a language to be translated, and the assembly language of the Intel ia32 family (used in PCs and some of our Solaris workstations downstairs) as a concrete example of a target machine. We study language translation first to learn some of techniques used that are useful for many programming problems outside of language translation, second to gain a better intuitive feel for the tools we use when programming and the costs of the programs we write, and third (possibly most important) to gain experience with the engineering problems associated with building and validating a substantial piece of software.
Please do not take this course unless you have the prerequisites: CS61B and CS61C, or equivalent courses (at a junior college, for example). You should be familiar with Java or C++. You need not be familiar with Python.
There is no required textbook for this course, since none is altogether satisfactory, and all tend to be ridiculously expensive. Officially, we'll rely on notes that I provide (on paper and on the web), but many people feel more comfortable if they can supplement this information with other treatments. You might want to take a look at the following books:
The major work in the course consists of building a system to translate programs written in a dialect of the popular scripting language Python. The system will be divided into modules, with each module constituting an assignment. The implementation language is C++ (!). In addition to the project, there will be a midterm, a final examination, and some ordinary written homework.
I encourage collaboration among teams, as long as it is restricted to questions of strategy as opposed to actual program text. Each partnership or individual is responsible for making it clear that their work is really theirs. Except for general-purpose utilities (e.g., a doubly-linked list package) you should not generally borrow other people's code. For anything you do borrow (including ideas) you must give proper credit in comments. Naturally, over-dependence on others' ideas will adversely affect your grade on a module, but failure to give credit where credit is due falls under the heading of "cheating."
Cheating (also known as plagiarism) is the presentation of someone else's work as your own. It will not be tolerated. Violators will fail the course and will be reported to the appropriate disciplinary agency. It is not possible for only one member of a partnership to cheat on a project assignment; any transgressions on your part will reflect equally on your partner.
In an attempt to cut down on cutthroat competitiveness and to make your grade a bit more meaningful, I use an absolute grading scale. Your letter grade will be determined by the total number of points on all assignments: A for 160–200 points, B for 130–160, C for 100–130, and D for 75–100, with plusses and minuses awarded to (roughly) the top and bottom third of each grade. These divisions are based on past classes' performances. Out of the total 200 points, the final counts for 50, the two additional tests for 20 apiece, and other written homework and project assignments total 110.
Ordinary homework doesn't get many points, because I see it mostly as a chance for exercise. You will be given full credit for handing in a solution in which you demonstrate that you have made a substantial effort on each problem. Since solutions will be available after the due date, late homework won't be graded.
Unless otherwise indicated, you should hand in all assignments electronically by the deadline given on the assignment. I'll penalize a project 5N/12 percent for each N hours it is late, rounded off in some unspecified fashion. During the course of the semester, however, we'll give you a total of four late days (96 hours) for free. For the first assignment, you'll have up to 32 hours of lateness for free. For the second assignment, you'll get another 32 hours, plus any you have left over from the first. Similarly for the last assignment. No, you cannot get late hours on credit; we won't move any of your Project 2 hours to Project 1. Needless to say, you are not obliged to turn in any of them late, and it is advisable never to be more than one day late. In general, it is the final submission (or partial submission) of something that counts, so making a change one day after a deadline is one day late. We will often forgive lateness for trivial changes, and we can ignore inadvertant late submissions entirely. Your best procedure, if you want to make a small change in an assignment and aren't sure whether we'll let you do it without lateness penalty, is to submit the change and then ask us. We can always undo a submission if it turns out to have been the wrong thing to do.
Page was last modified on Wed Nov 2 15:31:59 2011.