Lab 11: Interpreters
Due by 11:59pm on Wednesday, April 6.
Starter Files
Download lab11.zip. Inside the archive, you will find starter files for the questions in this lab, along with a copy of the Ok autograder.
Introduction
In the Scheme project, you'll be implementing a Python interpreter for Scheme.
Part of the process of interpreting Scheme expressions is being able to
parse a string of Scheme code as our input
into our interpreter's internal Python representation of Scheme expressions.
As all Scheme expressions are Scheme lists (and therefore linked lists),
we represent all Scheme expressions using the Pair
class,
which behaves as a linked list. This class is defined in pair.py
.
When given an input such as (+ 1 2)
,
there are two main steps we want to take.
The first part of interpreting expressions is taking the input
and breaking it down into each component.
In our example, we want to treat each of (
, +
, 1
, 2
, and )
as a separate token that we can then figure out how to represent.
This is called lexical analysis, and has been implemented for you
in the tokenize_lines
function in scheme_tokens.py
.
Now that we've broken down the input into its component parts,
we want to turn these Scheme tokens into our interpreter's internal
representations of them.
This is called syntactic analysis,
which happens in scheme_reader.py
in the scheme_read
and read_tail
functions.
(
tells us we are starting a call expression.+
will be the operator, as it's the first element in the call expression.1
is our first operand.2
is our second operand.)
tells us that we are ending the call expression.
The main idea is that we'd like to first recognize what the input represents, before we do any of the evaluating, or calling the operator on the operands, and so on.
The goal of this lab is to work with the various parts that go into parsing; while in this lab and in the project, we're focusing on the Scheme language, the general ideas of how we're setting up the Scheme interpreter can be applicable to other languages -- such as Python itself!
Required Questions
Check out the introduction for the context of this lab.
Part 1
Context
We store tokens ready to be parsed in Buffer
instances.
For example, a buffer containing the input (+ (2 3))
would have
the tokens '('
, '+'
, '('
, 2
, 3
, ')'
, and ')'
.
In this part, we will implement the Buffer
class.
A Buffer
provides a way of accessing a sequence of tokens across lines.
Its constructor takes an iterator, called "the source
", that returns the
next line of tokens as a list each time it is queried, until it runs out of
lines.
For example, source
could be defined as follows:
line1 = ['(', '+', 6, 1, ')'] # (+ 6 1)
line2 = ['(', 'quote', 'A', ')'] # (quote A)
line3 = [2, 1, 0] # 2 1 0
input_lines = [line1, line2, line3]
source = iter(input_lines)
In effect, the Buffer
combines the sequences returned from its source
and then supplies the items from them one at a time through its pop_first
method, calling the source
for more sequences of items only when needed.
In addition, Buffer
provides a current
instance attribute to look at the
next item to be supplied, without moving past it.
Problem 1
Important: Your code for this part should go in
buffer.py
.
Your job in this part is to implement the create_generator
, __init__
,
and pop_first
methods of the Buffer
class.
Note: For this question, you may want to use the built-in function
next
with itsdefault
argument. Here's an example:>>> iterator = iter([1, 2]) >>> next(iterator) # Here, there is no default arg given. 1 >>> next(iterator, 5) # Here, there is a default arg given, but not used. 2 >>> next(iterator, 5) # The iterator is exhausted, so next returns default. 5
For more about
next
, feel free to read through thenext
Python documentation.
create_generator
Implement create_generator
, a generator function which takes in source
,
an iterator over line(s), each of which is a list that contains token(s).
This function should yield a single token from a line of the source at a time.
If there are no more tokens on a line, then it should yield EOL_TOKEN
(an object that represents an end-of-line token).
If there are no more tokens in the entire source, it should have no more yields.
If you were to call next
on a generator of this function in this case,
a StopIteration
would be raised, as there would be no more applicable yields.
You can reference this function in your implementations for __init__
and
pop_first
.
Remember that generator functions can be used as follows:
>>> gen = some_generator_function() >>> next(gen) # Returns the first yield from some_generator_function >>> next(gen) # Returns the next yield from some_generator_function
__init__
__init__
takes in the input source source
.
You should define the following instance attributes:
- An instance attribute that holds a generator created by
create_generator
based off of thesource
, and self.current
to represent the current token of the generator that theBuffer
instance is on. In__init__
, the current token should be the very first token that the generator yields.
If you wish, you may define more instance attributes as you see fit.
pop_first
Implement pop_first
, which does the following:
- Saves the current token of the
Buffer
instance, to be returned later. - Updates the current token of the
Buffer
instance to the next token from its generator instance. - If there are no more tokens after the initial current token, then update
the current token to be
None
. (Hint: see the note on the default argument tonext
at the beginning of this problem.) - Returns the initial current token (not the updated current token!).
Testing your code
Use Ok to test your code:
python3 ok -q buffer
Part 2
Internal Representations
The reader will parse Scheme code into Python values with the following representations:
Input Example | Scheme Expression Type | Our Internal Representation |
---|---|---|
scm> 1
| Numbers | Python's built-in int and float values |
scm> x
| Symbols | Python's built-in string values |
scm> #t
| Booleans (#t , #f ) |
Python's built-in True , False values |
scm> (+ 2 3)
| Combinations | Instances of the Pair class, defined in
scheme_reader.py . This example is represented as:
Pair('+', Pair(2, Pair(3, nil))) . |
scm> nil
| nil |
The nil object, defined in
scheme_reader.py |
When we refer to combinations here, we are referring to both call expressions and special forms.
Problem 2
Important: Your code for this part should go in
scheme_reader.py
.
Important: While unlocking this problem, if the token yielded from the
Buffer
instance should beEOL_TOKEN
, it will be displayed according to the__repr__
function of theEOL_TOKEN
class. Specifically, you would get:>>> EOL_TOKEN This is a token representing the end of a line.
Your job in this part is to write the parsing functionality,
which consists of two mutually recursive functions:
scheme_read
and read_tail
.
Each function takes in a single src
parameter, which is a Buffer
instance.
scheme_read
removes enough tokens fromsrc
to form a single expression and returns that expression in the correct internal representation.read_tail
expects to read the rest of a list orPair
, assuming the open parenthesis of that list orPair
has already been removed byscheme_read
. It will read expressions (and thus remove tokens) until the matching closing parenthesis)
is seen. This list of expressions is returned as a linked list ofPair
instances.
In short, scheme_read
returns the next single complete expression in the
buffer and read_tail
returns the rest of a list or Pair
in the buffer.
Both functions mutate the buffer,
removing the tokens that have already been processed.
The behavior of both functions depends on the first token currently in src
.
They should be implemented as follows:
scheme_read
:
- If the current token is the string
"nil"
, return thenil
object. - If the current token is
(
, the expression is a pair or list. Callread_tail
on the rest ofsrc
and return its result. - If the current token is
'
, the rest of the buffer should be processed as aquote
expression. You will implement this portion in the next problem. - If the next token is not a delimiter, then it must be a primitive expression (i.e. a number, boolean). Return it. Provided
- If none of the above cases apply, raise an error. Provided
read_tail
:
- If there are no more tokens, then the list is missing a close parenthesis and we should raise an error. Provided
- If the token is
)
, then we've reached the end of the list or pair. Remove this token from the buffer and return thenil
object. If none of the above cases apply, the next token is the operator in a combination. For example,
src
could contain+ 2 3)
. To parse this:scheme_read
the next complete expression in the buffer.- Call
read_tail
to read the rest of the combination until the matching closing parenthesis. - Return the results as a
Pair
instance, where the first element is the next complete expression from (1) and the second element is the rest of the combination from (2).
Use Ok to unlock and test your code:
python3 ok -q scheme_read -u
python3 ok -q scheme_read
Problem 3
Important: Your code for this part should go in
scheme_reader.py
.
Your task in this problem is to complete the implementation of scheme_read
by allowing the function to now be able to handle quoted expressions.
In Scheme,
quoted expressions such as '<expr>
are equivalent to (quote <expr>)
.
That means that we need to wrap the expression following '
(which you can get by recursively calling scheme_read
)
into the quote
special form, which is a Scheme list
(as with all special forms).
In our representation,
a Pair
represents a Scheme list.
You should therefore wrap the expression following '
in a Pair
.
For example,
'bagel
, or ["'", "bagel"]
after being tokenized,
should be represented as Pair('quote', Pair('bagel', nil))
.
'(1 2)
(or ["'", "(", 1, 2, ")"]
)
should be represented as Pair('quote', Pair(Pair(1, Pair(2, nil)), nil))
.
Use Ok to unlock and test your code:
python3 ok -q quote -u
python3 ok -q quote
Running your parser
Now that your parser is complete, you can test the read-eval-print loop by running:
python3 scheme_reader.py --repl
Every time you type in a value into the prompt,
both the str
and repr
values of the parsed expression are printed.
You can try the following inputs:
read> 42
str : 42
repr: 42
read> nil
str : ()
repr: nil
read> (1 (2 3) (4 (5)))
str : (1 (2 3) (4 (5)))
repr: Pair(1, Pair(Pair(2, Pair(3, nil)), Pair(Pair(4, Pair(Pair(5, nil), nil)), nil)))
To exit the interpreter, you can type exit
.
Submit
Make sure to submit this assignment by running:
python3 ok --submit