| \documentstyle[11pt]{article} |
| \newcommand{\Cpp}{C\protect\raisebox{.18ex}{++}} |
| |
| \title{ |
| Interactively Testing Remote Servers Using the Python Programming Language |
| } |
| |
| \author{ |
| Guido van Rossum \\ |
| Dept. CST, CWI, P.O. Box 94079 \\ |
| 1090 GB Amsterdam, The Netherlands \\ |
| E-mail: {\tt guido@cwi.nl} |
| \and |
| Jelke de Boer \\ |
| HIO Enschede; P.O.Box 1326 \\ |
| 7500 BH Enschede, The Netherlands |
| } |
| |
| \begin{document} |
| |
| \maketitle |
| |
| \begin{abstract} |
| This paper describes how two tools that were developed quite |
| independently gained in power by a well-designed connection between |
| them. The tools are Python, an interpreted prototyping language, and |
| AIL, a Remote Procedure Call stub generator. The context is Amoeba, a |
| well-known distributed operating system developed jointly by the Free |
| University and CWI in Amsterdam. |
| |
| As a consequence of their integration, both tools have profited: |
| Python gained usability when used with Amoeba --- for which it was not |
| specifically developed --- and AIL users now have a powerful |
| interactive tool to test servers and to experiment with new |
| client/server interfaces.% |
| \footnote{ |
| An earlier version of this paper was presented at the Spring 1991 |
| EurOpen Conference in Troms{\o} under the title ``Linking a Stub |
| Generator (AIL) to a Prototyping Language (Python).'' |
| } |
| \end{abstract} |
| |
| \section{Introduction} |
| |
| Remote Procedure Call (RPC) interfaces, used in distributed systems |
| like Amoeba |
| \cite{Amoeba:IEEE,Amoeba:CACM}, |
| have a much more concrete character than local procedure call |
| interfaces in traditional systems. Because clients and servers may |
| run on different machines, with possibly different word size, byte |
| order, etc., much care is needed to describe interfaces exactly and to |
| implement them in such a way that they continue to work when a client |
| or server is moved to a different machine. Since machines may fail |
| independently, error handling must also be treated more carefully. |
| |
| A common approach to such problems is to use a {\em stub generator}. |
| This is a program that takes an interface description and transforms |
| it into functions that must be compiled and linked with client and |
| server applications. These functions are called by the application |
| code to take care of details of interfacing to the system's RPC layer, |
| to implement transformations between data representations of different |
| machines, to check for errors, etc. They are called `stubs' because |
| they don't actually perform the action that they are called for but |
| only relay the parameters to the server |
| \cite{RPC}. |
| |
| Amoeba's stub generator is called AIL, which stands for Amoeba |
| Interface Language |
| \cite{AIL}. |
| The first version of AIL generated only C functions, but an explicit |
| goal of AIL's design was {\em retargetability}: it should be possible |
| to add back-ends that generate stubs for different languages from the |
| same interface descriptions. Moreover, the stubs generated by |
| different back-ends must be {\em interoperable}: a client written in |
| Modula-3, say, should be able to use a server written in C, and vice |
| versa. |
| |
| This interoperability is the key to the success of the marriage |
| between AIL and Python. Python is a versatile interpreted language |
| developed by the first author. Originally intended as an alternative |
| for the kind of odd jobs that are traditionally solved by a mixture of |
| shell scripts, manually given shell commands, and an occasional ad hoc |
| C program, Python has evolved into a general interactive prototyping |
| language. It has been applied to a wide range of problems, from |
| replacements for large shell scripts to fancy graphics demos and |
| multimedia applications. |
| |
| One of Python's strengths is the ability for the user to type in some |
| code and immediately run it: no compilation or linking is necessary. |
| Interactive performance is further enhanced by Python's concise, clear |
| syntax, its very-high-level data types, and its lack of declarations |
| (which is compensated by run-time type checking). All this makes |
| programming in Python feel like a leisure trip compared to the hard |
| work involved in writing and debugging even a smallish C program. |
| |
| It should be clear by now that Python will be the ideal tool to test |
| servers and their interfaces. Especially during the development of a |
| complex server, one often needs to generate test requests on an ad hoc |
| basis, to answer questions like ``what happens if request X arrives |
| when the server is in state Y,'' to test the behavior of the server |
| with requests that touch its limitations, to check server responses to |
| all sorts of wrong requests, etc. Python's ability to immediately |
| execute `improvised' code makes it a much better tool for this |
| situation than C. |
| |
| The link to AIL extends Python with the necessary functionality to |
| connect to arbitrary servers, making the server testbed sketched above |
| a reality. Python's high-level data types, general programming |
| features, and system interface ensure that it has all the power and |
| flexibility needed for the job. |
| |
| One could go even further than this. Current distributed operating |
| systems, based on client-server interaction, all lack a good command |
| language or `shell' to give adequate access to available services. |
| Python has considerable potential for becoming such a shell. |
| |
| \subsection{Overview of this Paper} |
| |
| The rest of this paper contains three major sections and a conclusion. |
| First an overview of the Python programming language is given. Next |
| comes a short description of AIL, together with some relevant details |
| about Amoeba. Finally, the design and construction of the link |
| between Python and AIL is described in much detail. The conclusion |
| looks back at the work and points out weaknesses and strengths of |
| Python and AIL that were discovered in the process. |
| |
| \section{An Overview of Python} |
| |
| Python% |
| \footnote{ |
| Named after the funny TV show, not the nasty reptile. |
| } |
| owes much to ABC |
| \cite{ABC}, |
| a language developed at CWI as a programming language for non-expert |
| computer users. Python borrows freely from ABC's syntax and data |
| types, but adds modules, exceptions and classes, extensibility, and |
| the ability to call system functions. The concepts of modules, |
| exceptions and (to some extent) classes are influenced strongly by |
| their occurrence in Modula-3 |
| \cite{Modula-3}. |
| |
| Although Python resembles ABC in many ways, there is a a clear |
| difference in application domain. ABC is intended to be the only |
| programming language for those who use a computer as a tool, but |
| occasionally need to write a program. For this reason, ABC is not |
| just a programming language but also a programming environment, which |
| comes with an integrated syntax-directed editor and some source |
| manipulation commands. Python, on the other hand, aims to be a tool |
| for professional (system) programmers, for whom having a choice of |
| languages with different feature sets makes it possible to choose `the |
| right tool for the job.' The features added to Python make it more |
| useful than ABC in an environment where access to system functions |
| (such as file and directory manipulations) are common. They also |
| support the building of larger systems and libraries. The Python |
| implementation offers little in the way of a programming environment, |
| but is designed to integrate seamlessly with existing programming |
| environments (e.g. UNIX and Emacs). |
| |
| Perhaps the best introduction to Python is a short example. The |
| following is a complete Python program to list the contents of a UNIX |
| directory. |
| \begin{verbatim} |
| import sys, posix |
| |
| def ls(dirname): # Print sorted directory contents |
| names = posix.listdir(dirname) |
| names.sort() |
| for name in names: |
| if name[0] != '.': print name |
| |
| ls(sys.argv[1]) |
| \end{verbatim} |
| The largest part of this program, in the middle starting with {\tt |
| def}, is a function definition. It defines a function named {\tt ls} |
| with a single parameter called {\tt dirname}. (Comments in Python |
| start with `\#' and extend to the end of the line.) The function body |
| is indented: Python uses indentation for statement grouping instead of |
| braces or begin/end keywords. This is shorter to type and avoids |
| frustrating mismatches between the perception of grouping by the user |
| and the parser. Python accepts one statement per line; long |
| statements may be broken in pieces using the standard backslash |
| convention. If the body of a compound statement is a single, simple |
| statement, it may be placed on the same line as the head. |
| |
| The first statement of the function body calls the function {\tt |
| listdir} defined in the module {\tt posix}. This function returns a |
| list of strings representing the contents of the directory name passed |
| as a string argument, here the argument {\tt dirname}. If {\tt |
| dirname} were not a valid directory name, or perhaps not even a |
| string, {\tt listdir} would raise an exception and the next statement |
| would never be reached. (Exceptions can be caught in Python; see |
| later.) Assuming {\tt listdir} returns normally, its result is |
| assigned to the local variable {\tt names}. |
| |
| The second statement calls the method {\tt sort} of the variable {\tt |
| names}. This method is defined for all lists in Python and does the |
| obvious thing: the elements of the list are reordered according to |
| their natural ordering relationship. Since in our example the list |
| contains strings, they are sorted in ascending ASCII order. |
| |
| The last two lines of the function contain a loop that prints all |
| elements of the list whose first character isn't a period. In each |
| iteration, the {\tt for} statement assigns an element of the list to |
| the local variable {\tt name}. The {\tt print} statement is intended |
| for simple-minded output; more elaborate formatting is possible with |
| Python's string handling functions. |
| |
| The other two parts of the program are easily explained. The first |
| line is an {\tt import} statement that tells the interpreter to import |
| the modules {\tt sys} and {\tt posix}. As it happens these are both |
| built into the interpreter. Importing a module (built-in or |
| otherwise) only makes the module name available in the current scope; |
| functions and data defined in the module are accessed through the dot |
| notation as in {\tt posix.listdir}. The scope rules of Python are |
| such that the imported module name {\tt posix} is also available in |
| the function {\tt ls} (this will be discussed in more detail later). |
| |
| Finally, the last line of the program calls the {\tt ls} function with |
| a definite argument. It must be last since Python objects must be |
| defined before they can be used; in particular, the function {\tt ls} |
| must be defined before it can be called. The argument to {\tt ls} is |
| {\tt sys.argv[1]}, which happens to be the Python equivalent of {\tt |
| \$1} in a shell script or {\tt argv[1]} in a C program's {\tt main} |
| function. |
| |
| \subsection{Python Data Types} |
| |
| (This and the following subsections describe Python in quite a lot of |
| detail. If you are more interested in AIL, Amoeba and how they are |
| linked with Python, you can skip to section 3 now.) |
| |
| Python's syntax may not have big surprises (which is exactly as it |
| should be), but its data types are quite different from what is found |
| in languages like C, Ada or Modula-3. All data types in Python, even |
| integers, are `objects'. All objects participate in a common garbage |
| collection scheme (currently implemented using reference counting). |
| Assignment is cheap, independent of object size and type: only a |
| pointer to the assigned object is stored in the assigned-to variable. |
| No type checking is performed on assignment; only specific operations |
| like addition test for particular operand types. |
| |
| The basic object types in Python are numbers, strings, tuples, lists |
| and dictionaries. Some other object types are open files, functions, |
| modules, classes, and class instances; even types themselves are |
| represented as objects. Extension modules written in C can define |
| additional object types; examples are objects representing windows and |
| Amoeba capabilities. Finally, the implementation itself makes heavy |
| use of objects, and defines some private object types that aren't |
| normally visible to the user. There is no explicit pointer type in |
| Python. |
| |
| {\em Numbers}, both integers and floating point, are pretty |
| straightforward. The notation for numeric literals is the same as in |
| C, including octal and hexadecimal integers; precision is the same as |
| {\tt long} or {\tt double} in C\@. A third numeric type, `long |
| integer', written with an `L' suffix, can be used for arbitrary |
| precision calculations. All arithmetic, shifting and masking |
| operations from C are supported. |
| |
| {\em Strings} are `primitive' objects just like numbers. String |
| literals are written between single quotes, using similar escape |
| sequences as in C\@. Operations are built into the language to |
| concatenate and to replicate strings, to extract substrings, etc. |
| There is no limit to the length of the strings created by a program. |
| There is no separate character data type; strings of length one do |
| nicely. |
| |
| {\em Tuples} are a way to `pack' small amounts of heterogeneous data |
| together and carry them around as a unit. Unlike structure members in |
| C, tuple items are nameless. Packing and unpacking assignments allow |
| access to the items, for example: |
| \begin{verbatim} |
| x = 'Hi', (1, 2), 'World' # x is a 3-item tuple, |
| # its middle item is (1, 2) |
| p, q, r = x # unpack x into p, q and r |
| a, b = q # unpack q into a and b |
| \end{verbatim} |
| A combination of packing and unpacking assignment can be used as |
| parallel assignment, and is idiom for permutations, e.g.: |
| \begin{verbatim} |
| p, q = q, p # swap without temporary |
| a, b, c = b, c, a # cyclic permutation |
| \end{verbatim} |
| Tuples are also used for function argument lists if there is more than |
| one argument. A tuple object, once created, cannot be modified; but |
| it is easy enough to unpack it and create a new, modified tuple from |
| the unpacked items and assign this to the variable that held the |
| original tuple object (which will then be garbage-collected). |
| |
| {\em Lists} are array-like objects. List items may be arbitrary |
| objects and can be accessed and changed using standard subscription |
| notation. Lists support item insertion and deletion, and can |
| therefore be used as queues, stacks etc.; there is no limit to their |
| size. |
| |
| Strings, tuples and lists together are {\em sequence} types. These |
| share a common notation for generic operations on sequences such as |
| subscription, concatenation, slicing (taking subsequences) and |
| membership tests. As in C, subscripts start at 0. |
| |
| {\em Dictionaries} are `mappings' from one domain to another. The |
| basic operations on dictionaries are item insertion, extraction and |
| deletion, using subscript notation with the key as subscript. (The |
| current implementation allows only strings in the key domain, but a |
| future version of the language may remove this restriction.) |
| |
| \subsection{Statements} |
| |
| Python has various kinds of simple statements, such as assignments |
| and {\tt print} statements, and several kinds of compound statements, |
| like {\tt if} and {\tt for} statements. Formally, function |
| definitions and {\tt import} statements are also statements, and there |
| are no restrictions on the ordering of statements or their nesting: |
| {\tt import} may be used inside a function, functions may be defined |
| conditionally using an {\tt if} statement, etc. The effect of a |
| declaration-like statement takes place only when it is executed. |
| |
| All statements except assignments and expression statements begin with |
| a keyword: this makes the language easy to parse. An overview of the |
| most common statement forms in Python follows. |
| |
| An {\em assignment} has the general form |
| \vspace{\itemsep} |
| |
| \noindent |
| {\em variable $=$ variable $= ... =$ variable $=$ expression} |
| \vspace{\itemsep} |
| |
| It assigns the value of the expression to all listed variables. (As |
| shown in the section on tuples, variables and expressions can in fact |
| be comma-separated lists.) The assignment operator is not an |
| expression operator; there are no horrible things in Python like |
| \begin{verbatim} |
| while (p = p->next) { ... } |
| \end{verbatim} |
| Expression syntax is mostly straightforward and will not be explained |
| in detail here. |
| |
| An {\em expression statement} is just an expression on a line by |
| itself. This writes the value of the expression to standard output, |
| in a suitably unambiguous way, unless it is a `procedure call' (a |
| function call that returns no value). Writing the value is useful |
| when Python is used in `calculator mode', and reminds the programmer |
| not to ignore function results. |
| |
| The {\tt if} statement allows conditional execution. It has optional |
| {\tt elif} and {\tt else} parts; a construct like {\tt |
| if...elif...elif...elif...else} can be used to compensate for the |
| absence of a {\em switch} or {\em case} statement. |
| |
| Looping is done with {\tt while} and {\tt for} statements. The latter |
| (demonstrated in the `ls' example earlier) iterates over the elements |
| of a `sequence' (see the discussion of data types below). It is |
| possible to terminate a loop with a {\tt break} statement or to start |
| the next iteration with {\tt continue}. Both looping statements have |
| an optional {\tt else} clause which is executed after the loop is |
| terminated normally, but skipped when it is terminated by {\tt break}. |
| This can be handy for searches, to handle the case that the item is |
| not found. |
| |
| Python's {\em exception} mechanism is modelled after that of Modula-3. |
| Exceptions are raised by the interpreter when an illegal operation is |
| tried. It is also possible to explicitly raise an exception with the |
| {\tt raise} statement: |
| \vspace{\itemsep} |
| |
| \noindent |
| {\tt raise {\em expression}, {\em expression}} |
| \vspace{\itemsep} |
| |
| The first expression identifies which exception should be raised; |
| there are several built-in exceptions and the user may define |
| additional ones. The second, optional expression is passed to the |
| handler, e.g. as a detailed error message. |
| |
| Exceptions may be handled (caught) with the {\tt try} statement, which |
| has the following general form: |
| \vspace{\itemsep} |
| |
| \noindent |
| {\tt |
| \begin{tabular}{l} |
| try: {\em block} \\ |
| except {\em expression}, {\em variable}: {\em block} \\ |
| except {\em expression}, {\em variable}: {\em block} \\ |
| ... \\ |
| except: {\em block} |
| \end{tabular} |
| } |
| \vspace{\itemsep} |
| |
| When an exception is raised during execution of the first block, a |
| search for an exception handler starts. The first {\tt except} clause |
| whose {\em expression} matches the exception is executed. The |
| expression may specify a list of exceptions to match against. A |
| handler without an expression serves as a `catch-all'. If there is no |
| match, the search for a handler continues with outer {\tt try} |
| statements; if no match is found on the entire invocation stack, an |
| error message and stack trace are printed, and the program is |
| terminated (interactively, the interpreter returns to its main loop). |
| |
| Note that the form of the {\tt except} clauses encourages a style of |
| programming whereby only selected exceptions are caught, passing |
| unanticipated exceptions on to the caller and ultimately to the user. |
| This is preferable over a simpler `catch-all' error handling |
| mechanism, where a simplistic handler intended to catch a single type |
| of error like `file not found' can easily mask genuine programming |
| errors --- especially in a language like Python which relies strongly |
| on run-time checking and allows the catching of almost any type of |
| error. |
| |
| Other common statement forms, which we have already encountered, are |
| function definitions, {\tt import} statements and {\tt print} |
| statements. There is also a {\tt del} statement to delete one or more |
| variables, a {\tt return} statement to return from a function, and a |
| {\tt global} statement to allow assignments to global variables. |
| Finally, the {\tt pass} statement is a no-op. |
| |
| \subsection{Execution Model} |
| |
| A Python program is executed by a stack-based interpreter. |
| |
| When a function is called, a new `execution environment' for it is |
| pushed onto the stack. An execution environment contains (among other |
| data) pointers to two `symbol tables' that are used to hold variables: |
| the local and the global symbol table. The local symbol table |
| contains local variables of the current function invocation (including |
| the function arguments); the global symbol table contains variables |
| defined in the module containing the current function. |
| |
| The `global' symbol table is thus only global with respect to the |
| current function. There are no system-wide global variables; using |
| the {\tt import} statement it is easy enough to reference variables |
| that are defined in other modules. A system-wide read-only symbol |
| table is used for built-in functions and constants though. |
| |
| On assignment to a variable, by default an entry for it is made in the |
| local symbol table of the current execution environment. The {\tt |
| global} command can override this (it is not enough that a global |
| variable by the same name already exists). When a variable's value is |
| needed, it is searched first in the local symbol table, then in the |
| global one, and finally in the symbol table containing built-in |
| functions and constants. |
| |
| The term `variable' in this context refers to any name: functions and |
| imported modules are searched in exactly the same way. |
| |
| Names defined in a module's symbol table survive until the end of the |
| program. This approximates the semantics of file-static global |
| variables in C or module variables in Modula-3. A module is |
| initialized the first time it is imported, by executing the text of |
| the module as a parameterless function whose local and global symbol |
| tables are the same, so names are defined in module's symbol table. |
| (Modules implemented in C have another way to define symbols.) |
| |
| A Python main program is read from standard input or from a script |
| file passed as an argument to the interpreter. It is executed as if |
| an anonymous module was imported. Since {\tt import} statements are |
| executed like all other statements, the initialization order of the |
| modules used in a program is defined by the flow of control through |
| the program. |
| |
| The `attribute' notation {\em m.name}, where {\em m} is a module, |
| accesses the symbol {\em name} in that module's symbol table. It can |
| be assigned to as well. This is in fact a special case of the |
| construct {\em x.name} where {\em x} denotes an arbitrary object; the |
| type of {\em x} determines how this is to be interpreted, and what |
| assignment to it means. |
| |
| For instance, when {\tt a} is a list object, {\tt a.append} yields a |
| built-in `method' object which, when called, appends an item to {\tt a}. |
| (If {\tt a} and {\tt b} are distinct list objects, {\tt a.append} and |
| {\tt b.append} are distinguishable method objects.) Normally, in |
| statements like {\tt a.append(x)}, the method object {\tt a.append} is |
| called and then discarded, but this is a matter of convention. |
| |
| List attributes are read-only --- the user cannot define new list |
| methods. Some objects, like numbers and strings, have no attributes |
| at all. Like all type checking in Python, the meaning of an attribute |
| is determined at run-time --- when the parser sees {\em x.name}, it |
| has no idea of the type of {\em x}. Note that {\em x} here does not |
| have to be a variable --- it can be an arbitrary (perhaps |
| parenthesized) expression. |
| |
| Given the flexibility of the attribute notation, one is tempted to use |
| methods to replace all standard operations. Yet, Python has kept a |
| small repertoire of built-in functions like {\tt len()} and {\tt |
| abs()}. The reason is that in some cases the function notation is |
| more familiar than the method notation; just like programs would |
| become less readable if all infix operators were replaced by function |
| calls, they would become less readable if all function calls had to be |
| replaced by method calls (and vice versa!). |
| |
| The choice whether to make something a built-in function or a method |
| is a matter of taste. For arithmetic and string operations, function |
| notation is preferred, since frequently the argument to such an |
| operation is an expression using infix notation, as in {\tt abs(a+b)}; |
| this definitely looks better than {\tt (a+b).abs()}. The choice |
| between make something a built-in function or a function defined in a |
| built-in method (requiring {\tt import}) is similarly guided by |
| intuition; all in all, only functions needed by `general' programming |
| techniques are built-in functions. |
| |
| \subsection{Classes} |
| |
| Python has a class mechanism distinct from the object-orientation |
| already explained. A class in Python is not much more than a |
| collection of methods and a way to create class instances. Class |
| methods are ordinary functions whose first parameter is the class |
| instance; they are called using the method notation. |
| |
| For instance, a class can be defined as follows: |
| \begin{verbatim} |
| class Foo: |
| def meth1(self, arg): ... |
| def meth2(self): ... |
| \end{verbatim} |
| A class instance is created by |
| {\tt x = Foo()} |
| and its methods can be called thus: |
| \begin{verbatim} |
| x.meth1('Hi There!') |
| x.meth2() |
| \end{verbatim} |
| The functions used as methods are also available as attributes of the |
| class object, and the above method calls could also have been written |
| as follows: |
| \begin{verbatim} |
| Foo.meth1(x, 'Hi There!') |
| Foo.meth2(x) |
| \end{verbatim} |
| Class methods can store instance data by assigning to instance data |
| attributes, e.g.: |
| \begin{verbatim} |
| self.size = 100 |
| self.title = 'Dear John' |
| \end{verbatim} |
| Data attributes do not have to be declared; as with local variables, |
| they spring into existence when assigned to. It is a matter of |
| discretion to avoid name conflicts with method names. This facility |
| is also available to class users; instances of a method-less class can |
| be used as records with named fields. |
| |
| There is no built-in mechanism for instance initialization. Classes |
| by convention provide an {\tt init()} method which initializes the |
| instance and then returns it, so the user can write |
| \begin{verbatim} |
| x = Foo().init('Dr. Strangelove') |
| \end{verbatim} |
| |
| Any user-defined class can be used as a base class to derive other |
| classes. However, built-in types like lists cannot be used as base |
| classes. (Incidentally, the same is true in \Cpp{} and Modula-3.) A |
| class may override any method of its base classes. Instance methods |
| are first searched in the method list of their class, and then, |
| recursively, in the method lists of their base class. Initialization |
| methods of derived classes should explicitly call the initialization |
| methods of their base class. |
| |
| A simple form of multiple inheritance is also supported: a class can |
| have multiple base classes, but the language rules for resolving name |
| conflicts are somewhat simplistic, and consequently the feature has so |
| far found little usage. |
| |
| \subsection{The Python Library} |
| |
| Python comes with an extensive library, structured as a collection of |
| modules. A few modules are built into the interpreter: these |
| generally provide access to system libraries implemented in C such as |
| mathematical functions or operating system calls. Two built-in |
| modules provide access to internals of the interpreter and its |
| environment. Even abusing these internals will at most cause an |
| exception in the Python program; the interpreter will not dump core |
| because of errors in Python code. |
| |
| Most modules however are written in Python and distributed with the |
| interpreter; they provide general programming tools like string |
| operations and random number generators, provide more convenient |
| interfaces to some built-in modules, or provide specialized services |
| like a {\em getopt}-style command line option processor for |
| stand-alone scripts. |
| |
| There are also some modules written in Python that dig deep in the |
| internals of the interpreter; there is a module to browse the stack |
| backtrace when an unhandled exception has occurred, one to disassemble |
| the internal representation of Python code, and even an interactive |
| source code debugger which can trace Python code, set breakpoints, |
| etc. |
| |
| \subsection{Extensibility} |
| |
| It is easy to add new built-in modules written in C to the Python |
| interpreter. Extensions appear to the Python user as built-in |
| modules. Using a built-in module is no different from using a module |
| written in Python, but obviously the author of a built-in module can |
| do things that cannot be implemented purely in Python. |
| |
| In particular, built-in modules can contain Python-callable functions |
| that call functions from particular system libraries (`wrapper |
| functions'), and they can define new object types. In general, if a |
| built-in module defines a new object type, it should also provide at |
| least one function that creates such objects. Attributes of such |
| object types are also implemented in C; they can return data |
| associated with the object or methods, implemented as C functions. |
| |
| For instance, an extension was created for Amoeba: it provides wrapper |
| functions for the basic Amoeba name server functions, and defines a |
| `capability' object type, whose methods are file server operations. |
| Another extension is a built-in module called {\tt posix}; it provides |
| wrappers around post UNIX system calls. Extension modules also |
| provide access to two different windowing/graphics interfaces: STDWIN |
| \cite{STDWIN} |
| (which connects to X11 on UNIX and to the Mac Toolbox on the |
| Macintosh), and the Graphics Library (GL) for Silicon Graphics |
| machines. |
| |
| Any function in an extension module is supposed to type-check its |
| arguments; the interpreter contains a convenience function to |
| facilitate extracting C values from arguments and type-checking them |
| at the same time. Returning values is also painless, using standard |
| functions to create Python objects from C values. |
| |
| On some systems extension modules may be dynamically loaded, thus |
| avoiding the need to maintain a private copy of the Python interpreter |
| in order to use a private extension. |
| |
| \section{A Short Description of AIL and Amoeba} |
| |
| An RPC stub generator takes an interface description as input. The |
| designer of a stub generator has at least two choices for the input |
| language: use a suitably restricted version of the target language, or |
| design a new language. The first solution was chosen, for instance, |
| by the designers of Flume, the stub generator for the Topaz |
| distributed operating system built at DEC SRC |
| \cite{Flume,Evolving}. |
| |
| Flume's one and only target language is Modula-2+ (the predecessor of |
| Modula-3). Modula-2+, like Modula-N for any N, has an interface |
| syntax that is well suited as a stub generator input language: an |
| interface module declares the functions that are `exported' by a |
| module implementation, with their parameter and return types, plus the |
| types and constants used for the parameters. Therefore, the input to |
| Flume is simply a Modula-2+ interface module. But even in this ideal |
| situation, an RPC stub generator needs to know things about functions |
| that are not stated explicitly in the interface module: for instance, |
| the transfer direction of VAR parameters (IN, OUT or both) is not |
| given. Flume solves this and other problems by a mixture of |
| directives hidden in comments and a convention for the names of |
| objects. Thus, one could say that the designers of Flume really |
| created a new language, even though it looks remarkably like their |
| target language. |
| |
| \subsection{The AIL Input Language} |
| |
| Amoeba uses C as its primary programming language. C function |
| declarations (at least in `Classic' C) don't specify the types of |
| the parameters, let alone their transfer direction. Using this as |
| input for a stub generator would require almost all information for |
| the stub generator to be hidden inside comments, which would require a |
| rather contorted scanner. Therefore we decided to design the input |
| syntax for Amoeba's stub generator `from scratch'. This gave us the |
| liberty to invent proper syntax not only for the transfer direction of |
| parameters, but also for variable-length arrays. |
| |
| On the other hand we decided not to abuse our freedom, and borrowed as |
| much from C as we could. For instance, AIL runs its input through the |
| C preprocessor, so we get macros, include files and conditional |
| compilation for free. AIL's type declaration syntax is a superset of |
| C's, so the user can include C header files to use the types declared |
| there as function parameter types --- which are declared using |
| function prototypes as in \Cpp{} or Standard C\@. It should be clear by |
| now that AIL's lexical conventions are also identical to C's. The |
| same is true for its expression syntax. |
| |
| Where does AIL differ from C, then? Function declarations in AIL are |
| grouped in {\em classes}. Classes in AIL are mostly intended as a |
| grouping mechanism: all functions implemented by a server are grouped |
| together in a class. Inheritance is used to form new groups by adding |
| elements to existing groups; multiple inheritance is supported to join |
| groups together. Classes can also contain constant and type |
| definitions, and one form of output that AIL can generate is a header |
| file for use by C programmers who wish to use functions from a |
| particular AIL class. |
| |
| Let's have a look at some (unrealistically simple) class definitions: |
| \begin{verbatim} |
| #include <amoeba.h> /* Defines `capability', etc. */ |
| |
| class standard_ops [1000 .. 1999] { |
| /* Operations supported by most interfaces */ |
| std_info(*, out char buf[size:100], out int size); |
| std_destroy(*); |
| }; |
| \end{verbatim} |
| This defines a class called `standard\_ops' whose request codes are |
| chosen by AIL from the range 1000-1999. Request codes are small |
| integers used to identify remote operations. The author of the class |
| must specify a range from which AIL chooses, and class authors must |
| make sure they avoid conflicts, e.g. by using an `assigned number |
| administration office'. In the example, `std\_info' will be assigned |
| request code 1000 and `std\_destroy' will get code 1001. There is |
| also an option to explicitly assign request codes, for compatibility |
| with servers with manually written interfaces. |
| |
| The class `standard\_ops' defines two operations, `std\_info' and |
| `std\_destroy'. The first parameter of each operation is a star |
| (`*'); this is a placeholder for a capability that must be passed when |
| the operation is called. The description of Amoeba below explains the |
| meaning and usage of capabilities; for now, it is sufficient to know |
| that a capability is a small structure that uniquely identifies an |
| object and a server or service. |
| |
| The standard operation `std\_info' has two output parameters: a |
| variable-size character buffer (which will be filled with a short |
| descriptive string of the object to which the operation is applied) |
| and an integer giving the length of this string. The standard |
| operation `std\_destroy' has no further parameters --- it just |
| destroys the object, if the caller has the right to do so. |
| |
| The next class is called `tty': |
| \begin{verbatim} |
| class tty [2000 .. 2099] { |
| inherit standard_ops; |
| const TTY_MAXBUF = 1000; |
| tty_write(*, char buf[size:TTY_MAXBUF], int size); |
| tty_read(*, out char buf[size:TTY_MAXBUF], out int size); |
| }; |
| \end{verbatim} |
| The request codes for operations defined in this class lie in the |
| range 2000-2099; inherited operations use the request codes already |
| assigned to them. The operations defined by this class are |
| `tty\_read' and `tty\_write', which pass variable-sized data buffers |
| between client and server. Class `tty' inherits class |
| `standard\_ops', so tty objects also support the operations |
| `std\_info' and `std\_destroy'. |
| |
| Only the {\em interface} for `std\_info' and `std\_destroy' is shared |
| between tty objects and other objects whose interface inherits |
| `standard\_ops'; the implementation may differ. Even multiple |
| implementations of the `tty' interface may exist, e.g. a driver for a |
| console terminal and a terminal emulator in a window. To expand on |
| the latter example, consider: |
| \begin{verbatim} |
| class window [2100 .. 2199] { |
| inherit standard_ops; |
| win_create(*, int x, int y, int width, int height, |
| out capability win_cap); |
| win_reconfigure(*, int x, int y, int width, int height); |
| }; |
| |
| class tty_emulator [2200 .. 2299] { |
| inherit tty, window; |
| }; |
| \end{verbatim} |
| Here two new interface classes are defined. |
| Class `window' could be used for creating and manipulating windows. |
| Note that `win\_create' returns a capability for the new window. |
| This request should probably should be sent to a generic window |
| server capability, or it might create a subwindow when applied to a |
| window object. |
| |
| Class `tty\_emulator' demonstrates the essence of multiple inheritance. |
| It is presumably the interface to a window-based terminal emulator. |
| Inheritance is transitive, so `tty\_emulator' also implicitly inherits |
| `standard\_ops'. |
| In fact, it inherits it twice: once via `tty' and once via `window'. |
| Since AIL class inheritance only means interface sharing, not |
| implementation sharing, inheriting the same class multiple times is |
| never a problem and has the same effect as inheriting it once. |
| |
| Note that the power of AIL classes doesn't go as far as \Cpp{}. |
| AIL classes cannot have data members, and there is |
| no mechanism for a server that implements a derived class |
| to inherit the implementation of the base |
| class --- other than copying the source code. |
| The syntax for class definitions and inheritance is also different. |
| |
| \subsection{Amoeba} |
| |
| The smell of `object-orientedness' that the use of classes in AIL |
| creates matches nicely with Amoeba's object-oriented approach to |
| RPC\@. In Amoeba, almost all operating system entities (files, |
| directories, processes, devices etc.) are implemented as {\em |
| objects}. Objects are managed by {\em services} and represented by |
| {\em capabilities}. A capability gives its holder access to the |
| object it represents. Capabilities are protected cryptographically |
| against forgery and can thus be kept in user space. A capability is a |
| 128-bit binary string, subdivided as follows: |
| |
| % XXX Need a better version of this picture! |
| \begin{verbatim} |
| 48 24 8 48 Bits |
| +----------------+------------+--------+---------------+ |
| | Service | Object | Perm. | Check | |
| | port | number | bits | word | |
| +----------------+------------+--------+---------------+ |
| \end{verbatim} |
| |
| The service port is used by the RPC implementation in the Amoeba |
| kernel to locate a server implementing the service that manages the |
| object. In many cases there is a one-to-one correspondence between |
| servers and services (each service is implemented by exactly one |
| server process), but some services are replicated. For instance, |
| Amoeba's directory service, which is crucial for gaining access to most |
| other services, is implemented by two servers that listen on the same |
| port and know about exactly the same objects. |
| |
| The object number in the capability is used by the server receiving |
| the request for identifying the object to which the operation applies. |
| The permission bits specify which operations the holder of the capability |
| may apply. The last part of a capability is a 48-bit long `check |
| word', which is used to prevent forgery. The check word is computed |
| by the server based upon the permission bits and a random key per object |
| that it keeps secret. If you change the permission bits you must compute |
| the proper check word or else the server will refuse the capability. |
| Due to the size of the check word and the nature of the cryptographic |
| `one-way function' used to compute it, inverting this function is |
| impractical, so forging capabilities is impossible.% |
| \footnote{ |
| As computers become faster, inverting the one-way function becomes |
| less impractical. |
| Therefore, a next version of Amoeba will have 64-bit check words. |
| } |
| |
| A working Amoeba system is a collection of diverse servers, managing |
| files, directories, processes, devices etc. While most servers have |
| their own interface, there are some requests that make sense for some |
| or all object types. For instance, the {\em std\_info()} request, |
| which returns a short descriptive string, applies to all object types. |
| Likewise, {\em std\_destroy()} applies to files, directories and |
| processes, but not to devices. |
| |
| Similarly, different file server implementations may want to offer the |
| same interface for operations like {\em read()} and {\em write()} to |
| their clients. AIL's grouping of requests into classes is ideally |
| suited to describe this kind of interface sharing, and a class |
| hierarchy results which clearly shows the similarities between server |
| interfaces (not necessarily their implementations!). |
| |
| The base class of all classes defines the {\em std\_info()} request. |
| Most server interfaces actually inherit a derived class that also |
| defines {\em std\_destroy().} File servers inherit a class that |
| defines the common operations on files, etc. |
| |
| \subsection{How AIL Works} |
| |
| The AIL stub generator functions in three phases: |
| \begin{itemize} |
| \item |
| parsing, |
| \item |
| strategy determination, |
| \item |
| code generation. |
| \end{itemize} |
| |
| {\bf Phase one} parses the input and builds a symbol table containing |
| everything it knows about the classes and other definitions found in |
| the input. |
| |
| {\bf Phase two} determines the strategy to use for each function |
| declaration in turn and decides upon the request and reply message |
| formats. This is not a simple matter, because of various optimization |
| attempts. Amoeba's kernel interface for RPC requests takes a |
| fixed-size header and one arbitrary-size buffer. A large part of the |
| header holds the capability of the object to which the request is |
| directed, but there is some space left for a few integer parameters |
| whose interpretation is left up to the server. AIL tries to use these |
| slots for simple integer parameters, for two reasons. |
| |
| First, unlike the buffer, header fields are byte-swapped by the RPC |
| layer in the kernel if necessary, so it saves a few byte swapping |
| instructions in the user code. Second, and more important, a common |
| form of request transfers a few integers and one large buffer to or |
| from a server. The {\em read()} and {\em write()} requests of most |
| file servers have this form, for instance. If it is possible to place |
| all integer parameters in the header, the address of the buffer |
| parameter can be passed directly to the kernel RPC layer. While AIL |
| is perfectly capable of handling requests that do not fit this format, |
| the resulting code involves allocating a new buffer and copying all |
| parameters into it. It is a top priority to avoid this copying |
| (`marshalling') if at all possible, in order to maintain Amoeba's |
| famous RPC performance. |
| |
| When AIL resorts to copying parameters into a buffer, it reorders them |
| so that integers indicating the lengths of variable-size arrays are |
| placed in the buffer before the arrays they describe, since otherwise |
| decoding the request would be impossible. It also adds occasional |
| padding bytes to ensure integers are aligned properly in the buffer --- |
| this can speed up (un)marshalling. |
| |
| {\bf Phase three} is the code generator, or back-end. There are in |
| fact many different back-ends that may be called in a single run to |
| generate different types of output. The most important output types |
| are header files (for inclusion by the clients of an interface), |
| client stubs, and `server main loop' code. The latter decodes |
| incoming requests in the server. The generated code depends on the |
| programming language requested, and there are separate back-ends for |
| each supported language. |
| |
| It is important that the strategy chosen by phase two is independent |
| of the language requested for phase three --- otherwise the |
| interoperability of servers and clients written in different languages |
| would be compromised. |
| |
| \section{Linking AIL to Python} |
| |
| From the previous section it can be concluded that linking AIL to |
| Python is a matter of writing a back-end for Python. This is indeed |
| what we did. |
| |
| Considerable time went into the design of the back-end in order to |
| make the resulting RPC interface for Python fit as smoothly as |
| possible in Python's programming style. For instance, the issues of |
| parameter transfer, variable-size arrays, error handling, and call |
| syntax were all solved in a manner that favors ease of use in Python |
| rather than strict correspondence with the stubs generated for C, |
| without compromising network-level compatibility. |
| |
| \subsection{Mapping AIL Entities to Python} |
| |
| For each programming language that AIL is to support, a mapping must |
| be designed between the data types in AIL and those in that language. |
| Other aspects of the programming languages, such as differences in |
| function call semantics, must also be taken care of. |
| |
| While the mapping for C is mostly straightforward, the mapping for |
| Python requires a little thinking to get the best results for Python |
| programmers. |
| |
| \subsubsection{Parameter Transfer Direction} |
| |
| Perhaps the simplest issue is that of parameter transfer direction. |
| Parameters of functions declared in AIL are categorized as being of |
| type {\tt in}, {\tt out} or {\tt in} {\tt out} (the same distinction |
| as made in Ada). Python only has call-by-value parameter semantics; |
| functions can return multiple values as a tuple. This means that, |
| unlike the C back-end, the Python back-end cannot always generate |
| Python functions with exactly the same parameter list as the AIL |
| functions. |
| |
| Instead, the Python parameter list consists of all {\tt in} and {\tt |
| in} {\tt out} parameters, in the order in which they occur in the AIL |
| parameter list; similarly, the Python function returns a tuple |
| containing all {\tt in} {\tt out} and {\tt out} parameters. In fact |
| Python packs function parameters into a tuple as well, stressing the |
| symmetry between parameters and return value. For example, a stub |
| with this AIL parameter list: |
| \begin{verbatim} |
| (*, in int p1, in out int p2, in int p3, out int p4) |
| \end{verbatim} |
| will have the following parameter list and return values in Python: |
| \begin{verbatim} |
| (p1, p2, p3) -> (p2, p4) |
| \end{verbatim} |
| |
| \subsubsection{Variable-size Entities} |
| |
| The support for variable-size objects in AIL is strongly guided by the |
| limitations of C in this matter. Basically, AIL allows what is |
| feasible in C: functions may have variable-size arrays as parameters |
| (both input or output), provided their length is passed separately. |
| In practice this is narrowed to the following rule: for each |
| variable-size array parameter, there must be an integer parameter |
| giving its length. (An exception for null-terminated strings is |
| planned but not yet realized.) |
| |
| Variable-size arrays in AIL or C correspond to {\em sequences} in |
| Python: lists, tuples or strings. These are much easier to use than |
| their C counterparts. Given a sequence object in Python, it is always |
| possible to determine its size: the built-in function {\tt len()} |
| returns it. It would be annoying to require the caller of an RPC stub |
| with a variable-size parameter to also pass a parameter that |
| explicitly gives its size. Therefore we eliminate all parameters from |
| the Python parameter list whose value is used as the size of a |
| variable-size array. Such parameters are easily found: the array |
| bound expression contains the name of the parameter giving its size. |
| This requires the stub code to work harder (it has to recover the |
| value for size parameters from the corresponding sequence parameter), |
| but at least part of this work would otherwise be needed as well, to |
| check that the given and actual sizes match. |
| |
| Because of the symmetry in Python between the parameter list and the |
| return value of a function, the same elimination is performed on |
| return values containing variable-size arrays: integers returned |
| solely to tell the client the size of a returned array are not |
| returned explicitly to the caller in Python. |
| |
| \subsubsection{Error Handling} |
| |
| Another point where Python is really better than C is the issue of |
| error handling. It is a fact of life that everything involving RPC |
| may fail, for a variety of reasons outside the user's control: the |
| network may be disconnected, the server may be down, etc. Clients |
| must be prepared to handle such failures and recover from them, or at |
| least print an error message and die. In C this means that every |
| function returns an error status that must be checked by the caller, |
| causing programs to be cluttered with error checks --- or worse, |
| programs that ignore errors and carry on working with garbage data. |
| |
| In Python, errors are generally indicated by exceptions, which can be |
| handled out of line from the main flow of control if necessary, and |
| cause immediate program termination (with a stack trace) if ignored. |
| To profit from this feature, all RPC errors that may be encountered by |
| AIL-generated stubs in Python are turned into exceptions. An extra |
| value passed together with the exception is used to relay the error |
| code returned by the server to the handler. Since in general RPC |
| failures are rare, Python test programs can usually ignore exceptions |
| --- making the program simpler --- without the risk of occasional |
| errors going undetected. (I still remember the embarrassment of a |
| hundredfold speed improvement reported, long, long, ago, about a new |
| version of a certain program, which later had to be attributed to a |
| benchmark that silently dumped core...) |
| |
| \subsubsection{Function Call Syntax} |
| |
| Amoeba RPC operations always need a capability parameter (this is what |
| the `*' in the AIL function templates stands for); the service is |
| identified by the port field of the capability. In C, the capability |
| must always be the first parameter of the stub function, but in Python |
| we can do better. |
| |
| A Python capability is an opaque object type in its own right, which |
| is used, for instance, as parameter to and return value from Amoeba's |
| name server functions. Python objects can have methods, so it is |
| convenient to make all AIL-generated stubs methods of capabilities |
| instead of just functions. Therefore, instead of writing |
| \begin{verbatim} |
| some_stub(cap, other_parameters) |
| \end{verbatim} |
| as in C, Python programmers can write |
| \begin{verbatim} |
| cap.some_stub(other_parameters) |
| \end{verbatim} |
| This is better because it reduces name conflicts: in Python, no |
| confusion is possible between a stub and a local or global variable or |
| user-defined function with the same name. |
| |
| \subsubsection{Example} |
| |
| All the preceding principles can be seen at work in the following |
| example. Suppose a function is declared in AIL as follows: |
| \begin{verbatim} |
| some_stub(*, in char buf[size:1000], in int size, |
| out int n_done, out int status); |
| \end{verbatim} |
| In C it might be called by the following code (including declarations, |
| for clarity, but not initializations): |
| \begin{verbatim} |
| int err, n_done, status; |
| capability cap; |
| char buf[500]; |
| ... |
| err = some_stub(&cap, buf, sizeof buf, &n_done, &status); |
| if (err != 0) return err; |
| printf("%d done; status = %d\n", n_done, status); |
| \end{verbatim} |
| Equivalent code in Python might be the following: |
| \begin{verbatim} |
| cap = ... |
| buf = ... |
| n_done, status = cap.some_stub(buf) |
| print n_done, 'done;', 'status =', status |
| \end{verbatim} |
| No explicit error check is required in Python: if the RPC fails, an |
| exception is raised so the {\tt print} statement is never reached. |
| |
| \subsection{The Implementation} |
| |
| More or less orthogonal to the issue of how to map AIL operations to |
| the Python language is the question of how they should be implemented. |
| |
| In principle it would be possible to use the same strategy that is |
| used for C: add an interface to Amoeba's low-level RPC primitives to |
| Python and generate Python code to marshal parameters into and out of |
| a buffer. However, Python's high-level data types are not well suited |
| for marshalling: byte-level operations are clumsy and expensive, with |
| the result that marshalling a single byte of data can take several |
| Python statements. This would mean that a large amount of code would |
| be needed to implement a stub, which would cost a lot of time to parse |
| and take up a lot of space in `compiled' form (as parse tree or pseudo |
| code). Execution of the marshalling code would be sluggish as well. |
| |
| We therefore chose an alternate approach, writing the marshalling in |
| C, which is efficient at such byte-level operations. While it is easy |
| enough to generate C code that can be linked with the Python |
| interpreter, it would obviously not stimulate the use of Python for |
| server testing if each change to an interface required relinking the |
| interpreter (dynamic loading of C code is not yet available on |
| Amoeba). This is circumvented by the following solution: the |
| marshalling is handled by a simple {\em virtual machine}, and AIL |
| generates instructions for this machine. An interpreter for the |
| machine is linked into the Python interpreter and reads its |
| instructions from a file written by AIL. |
| |
| The machine language for our virtual machine is dubbed {\em Stubcode}. |
| Stubcode is a super-specialized language. There are two sets of of |
| about a dozen instructions each: one set marshals Python objects |
| representing parameters into a buffer, the other set (similar but not |
| quite symmetric) unmarshals results from a buffer into Python objects. |
| The Stubcode interpreter uses a stack to hold Python intermediate |
| results. Other state elements are an Amoeba header and buffer, a |
| pointer indicating the current position in the buffer, and of course a |
| program counter. Besides (un)marshalling, the virtual machine must |
| also implement type checking, and raise a Python exception when a |
| parameter does not have the expected type. |
| |
| The Stubcode interpreter marshals Python data types very efficiently, |
| since each instruction can marshal a large amount of data. For |
| instance, a whole Python string is marshalled by a single Stubcode |
| instruction, which (after some checking) executes the most efficient |
| byte-copying loop possible --- it calls {\tt memcpy()}. |
| |
| |
| Construction details of the Stubcode interpreter are straightforward. |
| Most complications are caused by the peculiarities of AIL's strategy |
| module and Python's type system. By far the most complex single |
| instruction is the `loop' instruction, which is used to marshal |
| arrays. |
| |
| As an example, here is the complete Stubcode program (with spaces and |
| comments added for clarity) generated for the function {\tt |
| some\_stub()} of the example above. The stack contains pointers to |
| Python objects, and its initial contents is the parameter to the |
| function, the string {\tt buf}. The final stack contents will be the |
| function return value, the tuple {\tt (n\_done, status)}. The name |
| {\tt header} refers to the fixed size Amoeba RPC header structure. |
| \vspace{1em} |
| |
| {\tt |
| \begin{tabular}{l l l} |
| BufSize & 1000 & {\em Allocate RPC buffer of 1000 bytes} \\ |
| Dup & 1 & {\em Duplicate stack top} \\ |
| StringS & & {\em Replace stack top by its string size} \\ |
| PutI & h\_extra int32 & {\em Store top element in }header.h\_extra \\ |
| TStringSlt & 1000 & {\em Assert string size less than 1000} \\ |
| PutVS & & {\em Marshal variable-size string} \\ |
| & & \\ |
| Trans & 1234 & {\em Execute the RPC (request code 1234)} \\ |
| & & \\ |
| GetI & h\_extra int32 & {\em Push integer from} header.h\_extra \\ |
| GetI & h\_size int32 & {\em Push integer from} header.h\_size \\ |
| Pack & 2 & {\em Pack top 2 elements into a tuple} \\ |
| \end{tabular} |
| } |
| \vspace{1em} |
| |
| As much work as possible is done by the Python back-end in AIL, rather |
| than in the Stubcode interpreter, to make the latter both simple and |
| fast. For instance, the decision to eliminate an array size parameter |
| from the Python parameter list is taken by AIL, and Stubcode |
| instructions are generated to recover the size from the actual |
| parameter and to marshal it properly. Similarly, there is a special |
| alignment instruction (not used in the example) to meet alignment |
| requirements. |
| |
| Communication between AIL and the Stubcode generator is via the file |
| system. For each stub function, AIL creates a file in its output |
| directory, named after the stub with a specific suffix. This file |
| contains a machine-readable version of the Stubcode program for the |
| stub. The Python user can specify a search path containing |
| directories which the interpreter searches for a Stubcode file the |
| first time the definition for a particular stub is needed. |
| |
| The transformations on the parameter list and data types needed to map |
| AIL data types to Python data types make it necessary to help the |
| Python programmer a bit in figuring out the parameters to a call. |
| Although in most cases the rules are simple enough, it is sometimes |
| hard to figure out exactly what the parameter and return values of a |
| particular stub are. There are two sources of help in this case: |
| first, the exception contains enough information so that the user can |
| figure what type was expected; second, AIL's Python back-end |
| optionally generates a human-readable `interface specification' file. |
| |
| \section{Conclusion} |
| |
| We have succeeded in creating a useful extension to Python that |
| enables Amoeba server writers to test and experiment with their server |
| in a much more interactive manner. We hope that this facility will |
| add to the popularity of AIL amongst Amoeba programmers. |
| |
| Python's extensibility was proven convincingly by the exercise |
| (performed by the second author) of adding the Stubcode interpreter to |
| Python. Standard data abstraction techniques are used to insulate |
| extension modules from details of the rest of the Python interpreter. |
| In the case of the Stubcode interpreter this worked well enough that |
| it survived a major overhaul of the main Python interpreter virtually |
| unchanged. |
| |
| On the other hand, adding a new back-end to AIL turned out to be quite |
| a bit of work. One problem, specific to Python, was to be expected: |
| Python's variable-size data types differ considerably from the |
| C-derived data model that AIL favors. Two additional problems we |
| encountered were the complexity of the interface between AIL's second |
| and third phases, and a number of remaining bugs in the second phase |
| that surfaced when the implementation of the Python back-end was |
| tested. The bugs have been tracked down and fixed, but nothing |
| has been done about the complexity of the interface. |
| |
| \subsection{Future Plans} |
| |
| AIL's C back-end generates server main loop code as well as client |
| stubs. The Python back-end currently only generates client stubs, so |
| it is not yet possible to write servers in Python. While it is |
| clearly more important to be able to use Python as a client than as a |
| server, the ability to write server prototypes in Python would be a |
| valuable addition: it allows server designers to experiment with |
| interfaces in a much earlier stage of the design, with a much smaller |
| programming effort. This makes it possible to concentrate on concepts |
| first, before worrying about efficient implementation. |
| |
| The unmarshalling done in the server is almost symmetric with the |
| marshalling in the client, and vice versa, so relative small |
| extensions to the Stubcode virtual machine will allow its use in a |
| server main loop. We hope to find the time to add this feature to a |
| future version of Python. |
| |
| \section{Availability} |
| |
| The Python source distribution is available to Internet users by |
| anonymous ftp to site {\tt ftp.cwi.nl} [IP address 192.16.184.180] |
| from directory {\tt /pub}, file name {\tt python*.tar.Z} (where the |
| {\tt *} stands for a version number). This is a compressed UNIX tar |
| file containing the C source and \LaTeX documentation for the Python |
| interpreter. It includes the Python library modules and the {\em |
| Stubcode} interpreter, as well as many example Python programs. Total |
| disk space occupied by the distribution is about 3 Mb; compilation |
| requires 1-3 Mb depending on the configuration built, the compile |
| options, etc. |
| |
| \bibliographystyle{plain} |
| |
| \bibliography{quabib} |
| |
| \end{document} |