Ruslan's Blog

Let’s Build A Simple Interpreter. Part 11.

I was sitting in my room the other day and thinking about how much we had covered, and I thought I would recap what we’ve learned so far and what lies ahead of us.

Up until now we’ve learned:

How to break sentences into tokens. The process is called lexical analysis and the part of the interpreter that does it is called a lexical analyzer, lexer, scanner, or tokenizer. We’ve learned how to write our own lexer from the ground up without using regular expressions or any other tools like Lex.
How to recognize a phrase in the stream of tokens. The process of recognizing a phrase in the stream of tokens or, to put it differently, the process of finding structure in the stream of tokens is called parsing or syntax analysis. The part of an interpreter or compiler that performs that job is called a parser or syntax analyzer.
How to represent a programming language’s syntax rules with syntax diagrams, which are a graphical representation of a programming language’s syntax rules. Syntax diagrams visually show us which statements are allowed in our programming language and which are not.
How to use another widely used notation for specifying the syntax of a programming language. It’s called context-free grammars (grammars, for short) or BNF (Backus-Naur Form).
How to map a grammar to code and how to write a recursive-descent parser.
How to write a really basic interpreter.
How associativity and precedence of operators work and how to construct a grammar using a precedence table.
How to build an Abstract Syntax Tree (AST) of a parsed sentence and how to represent the whole source program in Pascal as one big AST.
How to walk an AST and how to implement our interpreter as an AST node visitor.

With all that knowledge and experience under our belt, we’ve built an interpreter that can scan, parse, and build an AST and interpret, by walking the AST, our very first complete Pascal program. Ladies and gentlemen, I honestly think if you’ve reached this far, you deserve a pat on the back. But don’t let it go to your head. Keep going. Even though we’ve covered a lot of ground, there are even more exciting parts coming our way.

With everything we’ve covered so far, we are almost ready to tackle topics like:

Nested procedures and functions
Procedure and function calls
Semantic analysis (type checking, making sure variables are declared before they are used, and basically checking if a program makes sense)
Control flow elements (like IF statements)
Aggregate data types (Records)
More built-in types
Source-level debugger
Miscellanea (All the other goodness not mentioned above :)

But before we cover those topics, we need to build a solid foundation and infrastructure.

This is where we start diving deeper into the super important topic of symbols, symbol tables, and scopes. The topic itself will span several articles. It’s that important and you’ll see why. Okay, let’s start building that foundation and infrastructure, then, shall we?

First, let’s talk about symbols and why we need to track them. What is a symbol? For our purposes, we’ll informally define symbol as an identifier of some program entity like a variable, subroutine, or built-in type. For symbols to be useful they need to have at least the following information about the program entities they identify:

Name (for example, ‘x’, ‘y’, ‘number’)
Category (Is it a variable, subroutine, or built-in type?)
Type (INTEGER, REAL)

Today we’ll tackle variable symbols and built-in type symbols because we’ve already used variables and types before. By the way, the “built-in” type just means a type that hasn’t been defined by you and is available for you right out of the box, like INTEGER and REAL types that you’ve seen and used before.

Let’s take a look at the following Pascal program, specifically at the variable declaration part. You can see in the picture below that there are four symbols in that section: two variable symbols (x and y) and two built-in type symbols (INTEGER and REAL).

How can we represent symbols in code? Let’s create a base Symbol class in Python:

class Symbol(object):
    def __init__(self, name, type=None):
        self.name = name
        self.type = type

As you can see, the class takes the name parameter and an optional type parameter (not all symbols may have a type associated with them). What about the category of a symbol? We’ll encode the category of a symbol in the class name itself, which means we’ll create separate classes to represent different symbol categories.

Let’s start with basic built-in types. We’ve seen two built-in types so far, when we declared variables: INTEGER and REAL. How do we represent a built-in type symbol in code? Here is one option:

class BuiltinTypeSymbol(Symbol):
    def __init__(self, name):
        super(BuiltinTypeSymbol, self).__init__(name)

    def __str__(self):
        return self.name

    __repr__ = __str__

The class inherits from the Symbol class and the constructor requires only a name of the type. The category is encoded in the class name, and the type parameter from the base class for a built-in type symbol is None. The double underscore or dunder (as in “Double UNDERscore”) methods __str__ and __repr__ are special Python methods and we’ve defined them to have a nice formatted message when you print a symbol object.

Download the interpreter file and save it as spi.py; launch a python shell from the same directory where you saved the spi.py file, and play with the class we’ve just defined interactively:

$ python
>>> from spi import BuiltinTypeSymbol
>>> int_type = BuiltinTypeSymbol('INTEGER')
>>> int_type
INTEGER
>>> real_type = BuiltinTypeSymbol('REAL')
>>> real_type
REAL

How can we represent a variable symbol? Let’s create a VarSymbol class:

class VarSymbol(Symbol):
    def __init__(self, name, type):
        super(VarSymbol, self).__init__(name, type)

    def __str__(self):
        return '<{name}:{type}>'.format(name=self.name, type=self.type)

    __repr__ = __str__

In the class we made both the name and the type parameters required parameters and the class name VarSymbol clearly indicates that an instance of the class will identify a variable symbol (the category is variable.)

Back to the interactive python shell to see how we can manually construct instances for our variable symbols now that we know how to construct BuiltinTypeSymbol class instances:

$ python
>>> from spi import BuiltinTypeSymbol, VarSymbol
>>> int_type = BuiltinTypeSymbol('INTEGER')
>>> real_type = BuiltinTypeSymbol('REAL')
>>>
>>> var_x_symbol = VarSymbol('x', int_type)
>>> var_x_symbol
<x:INTEGER>
>>> var_y_symbol = VarSymbol('y', real_type)
>>> var_y_symbol
<y:REAL>

As you can see, we first create an instance of a built-in type symbol and then pass it as a parameter to VarSymbol‘s constructor.

Here is the hierarchy of symbols we’ve defined in visual form:

So far so good, but we haven’t answered the question yet as to why we even need to track those symbols in the first place.

Here are some of the reasons:

To make sure that when we assign a value to a variable the types are correct (type checking)
To make sure that a variable is declared before it is used

Take a look at the following incorrect Pascal program, for example:

There are two problems with the program above (you can compile it with fpc to see it for yourself):

In the expression “x := 2 + y;” we assigned a decimal value to the variable “x” that was declared as integer. That wouldn’t compile because the types are incompatible.
In the assignment statement “x := a;” we referenced the variable “a” that wasn’t declared - wrong!

To be able to identify cases like that even before interpreting/evaluating the source code of the program at run-time, we need to track program symbols. And where do we store the symbols that we track? I think you’ve guessed it right - in the symbol table!

What is a symbol table? A symbol table is an abstract data type (ADT) for tracking various symbols in source code. Today we’re going to implement our symbol table as a separate class with some helper methods:

class SymbolTable(object):
    def __init__(self):
        self._symbols = OrderedDict()

    def __str__(self):
        s = 'Symbols: {symbols}'.format(
            symbols=[value for value in self._symbols.values()]
        )
        return s

    __repr__ = __str__

    def define(self, symbol):
        print('Define: %s' % symbol)
        self._symbols[symbol.name] = symbol

    def lookup(self, name):
        print('Lookup: %s' % name)
        symbol = self._symbols.get(name)
        # 'symbol' is either an instance of the Symbol class or 'None'
        return symbol

There are two main operations that we will be performing with the symbol table: storing symbols and looking them up by name: hence, we need two helper methods - define and lookup.

The method define takes a symbol as a parameter and stores it internally in its _symbols ordered dictionary using the symbol’s name as a key and the symbol instance as a value. The method lookup takes a symbol name as a parameter and returns a symbol if it finds it or “None” if it doesn’t.

Let’s manually populate our symbol table for the same Pascal program we’ve used just recently where we were manually creating variable and built-in type symbols:

PROGRAM Part11;
VAR
   x : INTEGER;
   y : REAL;

BEGIN

END.

Launch a Python shell again and follow along:

$ python
>>> from spi import SymbolTable, BuiltinTypeSymbol, VarSymbol
>>> symtab = SymbolTable()
>>> int_type = BuiltinTypeSymbol('INTEGER')
>>> symtab.define(int_type)
Define: INTEGER
>>> symtab
Symbols: [INTEGER]
>>>
>>> var_x_symbol = VarSymbol('x', int_type)
>>> symtab.define(var_x_symbol)
Define: <x:INTEGER>
>>> symtab
Symbols: [INTEGER, <x:INTEGER>]
>>>
>>> real_type = BuiltinTypeSymbol('REAL')
>>> symtab.define(real_type)
Define: REAL
>>> symtab
Symbols: [INTEGER, <x:INTEGER>, REAL]
>>>
>>> var_y_symbol = VarSymbol('y', real_type)
>>> symtab.define(var_y_symbol)
Define: <y:REAL>
>>> symtab
Symbols: [INTEGER, <x:INTEGER>, REAL, <y:REAL>]

If you looked at the contents of the _symbols dictionary it would look something like this:

How do we automate the process of building the symbol table? We’ll just write another node visitor that walks the AST built by our parser! This is another example of how useful it is to have an intermediary form like AST. Instead of extending our parser to deal with the symbol table, we separate concerns and write a new node visitor class. Nice and clean. :)

Before doing that, though, let’s extend our SymbolTable class to initialize the built-in types when the symbol table instance is created. Here is the full source code for today’s SymbolTable class:

class SymbolTable(object):
    def __init__(self):
        self._symbols = OrderedDict()
        self._init_builtins()

    def _init_builtins(self):
        self.define(BuiltinTypeSymbol('INTEGER'))
        self.define(BuiltinTypeSymbol('REAL'))

    def __str__(self):
        s = 'Symbols: {symbols}'.format(
            symbols=[value for value in self._symbols.values()]
        )
        return s

    __repr__ = __str__

    def define(self, symbol):
        print('Define: %s' % symbol)
        self._symbols[symbol.name] = symbol

    def lookup(self, name):
        print('Lookup: %s' % name)
        symbol = self._symbols.get(name)
        # 'symbol' is either an instance of the Symbol class or 'None'
        return symbol

Now onto the SymbolTableBuilder AST node visitor:

class SymbolTableBuilder(NodeVisitor):
    def __init__(self):
        self.symtab = SymbolTable()

    def visit_Block(self, node):
        for declaration in node.declarations:
            self.visit(declaration)
        self.visit(node.compound_statement)

    def visit_Program(self, node):
        self.visit(node.block)

    def visit_BinOp(self, node):
        self.visit(node.left)
        self.visit(node.right)

    def visit_Num(self, node):
        pass

    def visit_UnaryOp(self, node):
        self.visit(node.expr)

    def visit_Compound(self, node):
        for child in node.children:
            self.visit(child)

    def visit_NoOp(self, node):
        pass

    def visit_VarDecl(self, node):
        type_name = node.type_node.value
        type_symbol = self.symtab.lookup(type_name)
        var_name = node.var_node.value
        var_symbol = VarSymbol(var_name, type_symbol)
        self.symtab.define(var_symbol)

You’ve seen most of those methods before in the Interpreter class, but the visit_VarDecl method deserves some special attention. Here it is again:

def visit_VarDecl(self, node):
    type_name = node.type_node.value
    type_symbol = self.symtab.lookup(type_name)
    var_name = node.var_node.value
    var_symbol = VarSymbol(var_name, type_symbol)
    self.symtab.define(var_symbol)

This method is responsible for visiting (walking) a VarDecl AST node and storing the corresponding symbol in the symbol table. First, the method looks up the built-in type symbol by name in the symbol table, then it creates an instance of the VarSymbol class and stores (defines) it in the symbol table.

Let’s take our SymbolTableBuilder AST walker for a test drive and see it in action:

$ python
>>> from spi import Lexer, Parser, SymbolTableBuilder
>>> text = """
... PROGRAM Part11;
... VAR
...    x : INTEGER;
...    y : REAL;
...
... BEGIN
...
... END.
... """
>>> lexer = Lexer(text)
>>> parser = Parser(lexer)
>>> tree = parser.parse()
>>> symtab_builder = SymbolTableBuilder()
Define: INTEGER
Define: REAL
>>> symtab_builder.visit(tree)
Lookup: INTEGER
Define: <x:INTEGER>
Lookup: REAL
Define: <y:REAL>
>>> # Let’s examine the contents of our symbol table
…
>>> symtab_builder.symtab
Symbols: [INTEGER, REAL, <x:INTEGER>, <y:REAL>]

In the interactive session above, you can see the sequence of “Define: …” and “Lookup: …” messages that indicate the order in which symbols are defined and looked up in the symbol table. The last command in the session prints the contents of the symbol table and you can see that it’s exactly the same as the contents of the symbol table that we’ve built manually before. The magic of AST node visitors is that they pretty much do all the work for you. :)

We can already put our symbol table and symbol table builder to good use: we can use them to verify that variables are declared before they are used in assignments and expressions. All we need to do is just extend the visitor with two more methods: visit_Assign and visit_Var:

def visit_Assign(self, node):
    var_name = node.left.value
    var_symbol = self.symtab.lookup(var_name)
    if var_symbol is None:
        raise NameError(repr(var_name))

    self.visit(node.right)

def visit_Var(self, node):
    var_name = node.value
    var_symbol = self.symtab.lookup(var_name)

    if var_symbol is None:
        raise NameError(repr(var_name))

These methods will raise a NameError exception if they cannot find the symbol in the symbol table.

Take a look at the following program, where we reference the variable “b” that hasn’t been declared yet:

PROGRAM NameError1;
VAR
   a : INTEGER;

BEGIN
   a := 2 + b;
END.

Let’s see what happens if we construct an AST for the program and pass it to our symbol table builder to visit:

$ python
>>> from spi import Lexer, Parser, SymbolTableBuilder
>>> text = """
... PROGRAM NameError1;
... VAR
...    a : INTEGER;
...
... BEGIN
...    a := 2 + b;
... END.
... """
>>> lexer = Lexer(text)
>>> parser = Parser(lexer)
>>> tree = parser.parse()
>>> symtab_builder = SymbolTableBuilder()
Define: INTEGER
Define: REAL
>>> symtab_builder.visit(tree)
Lookup: INTEGER
Define: <a:INTEGER>
Lookup: a
Lookup: b
Traceback (most recent call last):
  ...
  File "spi.py", line 674, in visit_Var
    raise NameError(repr(var_name))
NameError: 'b'

Exactly what we were expecting!

Here is another error case where we try to assign a value to a variable that hasn’t been defined yet, in this case the variable ‘a’:

PROGRAM NameError2;
VAR
   b : INTEGER;

BEGIN
   b := 1;
   a := b + 2;
END.

Meanwhile, in the Python shell:

>>> from spi import Lexer, Parser, SymbolTableBuilder
>>> text = """
... PROGRAM NameError2;
... VAR
...    b : INTEGER;
...
... BEGIN
...    b := 1;
...    a := b + 2;
... END.
... """
>>> lexer = Lexer(text)
>>> parser = Parser(lexer)
>>> tree = parser.parse()
>>> symtab_builder = SymbolTableBuilder()
Define: INTEGER
Define: REAL
>>> symtab_builder.visit(tree)
Lookup: INTEGER
Define: <b:INTEGER>
Lookup: b
Lookup: a
Traceback (most recent call last):
  ...
  File "spi.py", line 665, in visit_Assign
    raise NameError(repr(var_name))
NameError: 'a'

Great, our new visitor caught this problem too!

I would like to emphasize the point that all those checks that our SymbolTableBuilder AST visitor makes are made before the run-time, so before our interpreter actually evaluates the source program. To drive the point home if we were to interpret the following program:

PROGRAM Part11;
VAR
   x : INTEGER;
BEGIN
   x := 2;
END.

The contents of the symbol table and the run-time GLOBAL_MEMORY right before the program exited would look something like this:

Do you see the difference? Can you see that the symbol table doesn’t hold the value 2 for variable “x”? That’s solely the interpreter’s job now.

Remember the picture from Part 9 where the Symbol Table was used as global memory?

No more! We effectively got rid of the hack where symbol table did double duty as global memory.

Let’s put it all together and test our new interpreter with the following program:

PROGRAM Part11;
VAR
   number : INTEGER;
   a, b   : INTEGER;
   y      : REAL;

BEGIN {Part11}
   number := 2;
   a := number ;
   b := 10 * a + 10 * number DIV 4;
   y := 20 / 7 + 3.14
END.  {Part11}

Save the program as part11.pas and fire up the interpreter:

$ python spi.py part11.pas
Define: INTEGER
Define: REAL
Lookup: INTEGER
Define: <number:INTEGER>
Lookup: INTEGER
Define: <a:INTEGER>
Lookup: INTEGER
Define: <b:INTEGER>
Lookup: REAL
Define: <y:REAL>
Lookup: number
Lookup: a
Lookup: number
Lookup: b
Lookup: a
Lookup: number
Lookup: y

Symbol Table contents:
Symbols: [INTEGER, REAL, <number:INTEGER>, <a:INTEGER>, <b:INTEGER>, <y:REAL>]

Run-time GLOBAL_MEMORY contents:
a = 2
b = 25
number = 2
y = 5.99714285714

I’d like to draw your attention again to the fact that the Interpreter class has nothing to do with building the symbol table and it relies on the SymbolTableBuilder to make sure that the variables in the source code are properly declared before they are used by the Interpreter.

Check your understanding

What is a symbol?
Why do we need to track symbols?
What is a symbol table?
What is the difference between defining a symbol and resolving/looking up the symbol?
Given the following small Pascal program, what would be the contents of the symbol table, the global memory (the GLOBAL_MEMORY dictionary that is part of the Interpreter)?
```
PROGRAM Part11;
VAR
   x, y : INTEGER;
BEGIN
   x := 2;
   y := 3 + x;
END.
```

That’s all for today. In the next article, I’ll talk about scopes and we’ll get our hands dirty with parsing nested procedures. Stay tuned and see you soon! And remember that no matter what, “Keep going!”

P.S. My explanation of the topic of symbols and symbol table management is heavily influenced by the book Language Implementation Patterns by Terence Parr. It’s a terrific book. I think it has the clearest explanation of the topic I’ve ever seen and it also covers class scopes, a subject that I’m not going to cover in the series because we will not be discussing object-oriented Pascal.

P.P.S.: If you can’t wait and want to start digging into compilers, I highly recommend the freely available classic by Jack Crenshaw “Let’s Build a Compiler.”

By the way, I’m writing a book “Let’s Build A Web Server: First Steps” that explains how to write a basic web server from scratch. You can get a feel for the book here, here, and here. Subscribe to the mailing list to get the latest updates about the book and the release date.

All articles in this series:

Let’s Build A Simple Interpreter. Part 10.

Today we will continue closing the gap between where we are right now and where we want to be: a fully functional interpreter for a subset of Pascal programming language.

In this article we will update our interpreter to parse and interpret our very first complete Pascal program. The program can also be compiled by the Free Pascal compiler, fpc.

Here is the program itself:

PROGRAM Part10;
VAR
   number     : INTEGER;
   a, b, c, x : INTEGER;
   y          : REAL;

BEGIN {Part10}
   BEGIN
      number := 2;
      a := number;
      b := 10 * a + 10 * number DIV 4;
      c := a - - b
   END;
   x := 11;
   y := 20 / 7 + 3.14;
   { writeln('a = ', a); }
   { writeln('b = ', b); }
   { writeln('c = ', c); }
   { writeln('number = ', number); }
   { writeln('x = ', x); }
   { writeln('y = ', y); }
END.  {Part10}

Before we start digging into the details, download the source code of the interpreter from GitHub and the Pascal source code above, and try it on the command line:

$ python spi.py part10.pas
a = 2
b = 25
c = 27
number = 2
x = 11
y = 5.99714285714

If I remove the comments around the writeln statements in the part10.pas file, compile the source code with fpc and then run the produced executable, this is what I get on my laptop:

$ fpc part10.pas
$ ./part10
a = 2
b = 25
c = 27
number = 2
x = 11
y =  5.99714285714286E+000

Okay, let’s see what we’re going cover today:

We will learn how to parse and interpret the Pascal PROGRAM header
We will learn how to parse Pascal variable declarations
We will update our interpreter to use the DIV keyword for integer division and a forward slash / for float division
We will add support for Pascal comments

Let’s dive in and look at the grammar changes first. Today we will add some new rules and update some of the existing rules.

The program definition grammar rule is updated to include the PROGRAM reserved keyword, the program name, and a block that ends with a dot. Here is an example of a complete Pascal program:
```
PROGRAM Part10;
BEGIN
END.
```
The block rule combines a declarations rule and a compound_statement rule. We’ll also use the rule later in the series when we add procedure declarations. Here is an example of a block:
```
VAR
   number : INTEGER;

BEGIN
END
```
Here is another example:
```
BEGIN
END
```
Pascal declarations have several parts and each part is optional. In this article, we’ll cover the variable declaration part only. The declarations rule has either a variable declaration sub-rule or it’s empty.
Pascal is a statically typed language, which means that every variable needs a variable declaration that explicitly specifies its type. In Pascal, variables must be declared before they are used. This is achieved by declaring variables in the program variable declaration section using the VAR reserved keyword. You can define variables like this:
```
VAR
   number     : INTEGER;
   a, b, c, x : INTEGER;
   y          : REAL;
```
The type_spec rule is for handling INTEGER and REAL types and is used in variable declarations. In the example below
```
VAR
   a : INTEGER;
   b : REAL;
```
the variable “a” is declared with the type INTEGER and the variable “b” is declared with the type REAL (float). In this article we won’t enforce type checking, but we will add type checking later in the series.
The term rule is updated to use the DIV keyword for integer division and a forward slash / for float division.

Before, dividing 20 by 7 using a forward slash would produce an INTEGER 2:
```
20 / 7 = 2
```
Now, dividing 20 by 7 using a forward slash will produce a REAL (floating point number) 2.85714285714 :
```
20 / 7 = 2.85714285714
```
From now on, to get an INTEGER instead of a REAL, you need to use the DIV keyword:
```
20 DIV 7 = 2
```
The factor rule is updated to handle both integer and real (float) constants. I also removed the INTEGER sub-rule because the constants will be represented by INTEGER_CONST and REAL_CONST tokens and the INTEGER token will be used to represent the integer type. In the example below the lexer will generate an INTEGER_CONST token for 20 and 7 and a REAL_CONST token for 3.14 :
```
y := 20 / 7 + 3.14;
```

Here is our complete grammar for today:

    program : PROGRAM variable SEMI block DOT

    block : declarations compound_statement

    declarations : VAR (variable_declaration SEMI)+
                 | empty

    variable_declaration : ID (COMMA ID)* COLON type_spec

    type_spec : INTEGER

    compound_statement : BEGIN statement_list END

    statement_list : statement
                   | statement SEMI statement_list

    statement : compound_statement
              | assignment_statement
              | empty

    assignment_statement : variable ASSIGN expr

    empty :

    expr : term ((PLUS | MINUS) term)*

    term : factor ((MUL | INTEGER_DIV | FLOAT_DIV) factor)*

    factor : PLUS factor
           | MINUS factor
           | INTEGER_CONST
           | REAL_CONST
           | LPAREN expr RPAREN
           | variable

    variable: ID

In the rest of the article we’ll go through the same drill we went through last time:

Update the lexer
Update the parser
Update the interpreter

Updating the Lexer

Here is a summary of the lexer changes:

New tokens
New and updated reserved keywords
New skip_comments method to handle Pascal comments
Rename the integer method and make some changes to the method itself
Update the get_next_token method to return new tokens

Let’s dig into the changes mentioned above:

To handle a program header, variable declarations, integer and float constants as well as integer and float division, we need to add some new tokens - some of which are reserved keywords - and we also need to update the meaning of the INTEGER token to represent the integer type and not an integer constant. Here is a complete list of new and updated tokens:
- PROGRAM (reserved keyword)
- VAR (reserved keyword)
- COLON (:)
- COMMA (,)
- INTEGER (we change it to mean integer type and not integer constant like 3 or 5)
- REAL (for Pascal REAL type)
- INTEGER_CONST (for example, 3 or 5)
- REAL_CONST (for example, 3.14 and so on)
- INTEGER_DIV for integer division (the DIV reserved keyword)
- FLOAT_DIV for float division ( forward slash / )

Here is the complete mapping of reserved keywords to tokens:

RESERVED_KEYWORDS = {
    'PROGRAM': Token('PROGRAM', 'PROGRAM'),
    'VAR': Token('VAR', 'VAR'),
    'DIV': Token('INTEGER_DIV', 'DIV'),
    'INTEGER': Token('INTEGER', 'INTEGER'),
    'REAL': Token('REAL', 'REAL'),
    'BEGIN': Token('BEGIN', 'BEGIN'),
    'END': Token('END', 'END'),
}

We’re adding the skip_comment method to handle Pascal comments. The method is pretty basic and all it does is discard all the characters until the closing curly brace is found:
```
def skip_comment(self):
    while self.current_char != '}':
        self.advance()
    self.advance()  # the closing curly brace
```

We are renaming the integer method the number method. It can handle both integer constants and float constants like 3 and 3.14:

def number(self):
    """Return a (multidigit) integer or float consumed from the input."""
    result = ''
    while self.current_char is not None and self.current_char.isdigit():
        result += self.current_char
        self.advance()

    if self.current_char == '.':
        result += self.current_char
        self.advance()

        while (
            self.current_char is not None and
            self.current_char.isdigit()
        ):
            result += self.current_char
            self.advance()

        token = Token('REAL_CONST', float(result))
    else:
        token = Token('INTEGER_CONST', int(result))

    return token

We’re also updating the get_next_token method to return new tokens:

def get_next_token(self):
    while self.current_char is not None:
        ...
        if self.current_char == '{':
            self.advance()
            self.skip_comment()
            continue
        ...
        if self.current_char.isdigit():
            return self.number()

        if self.current_char == ':':
            self.advance()
            return Token(COLON, ':')

        if self.current_char == ',':
            self.advance()
            return Token(COMMA, ',')
        ...
        if self.current_char == '/':
            self.advance()
            return Token(FLOAT_DIV, '/')
        ...

Updating the Parser

Now onto the parser changes.

Here is a summary of the changes:

New AST nodes: Program, Block, VarDecl, Type
New methods corresponding to new grammar rules: block, declarations, variable_declaration, and type_spec.
Updates to the existing parser methods: program, term, and factor

Let’s go over the changes one by one:

We’ll start with new AST nodes first. There are four new nodes:

The Program AST node represents a program and will be our root node

class Program(AST):
    def __init__(self, name, block):
        self.name = name
        self.block = block

The Block AST node holds declarations and a compound statement:

class Block(AST):
    def __init__(self, declarations, compound_statement):
        self.declarations = declarations
        self.compound_statement = compound_statement

The VarDecl AST node represents a variable declaration. It holds a variable node and a type node:

class VarDecl(AST):
    def __init__(self, var_node, type_node):
        self.var_node = var_node
        self.type_node = type_node

The Type AST node represents a variable type (INTEGER or REAL):

class Type(AST):
    def __init__(self, token):
        self.token = token
        self.value = token.value

As you probably remember, each rule from the grammar has a corresponding method in our recursive-descent parser. Today we’re adding four new methods: block, declarations, variable_declaration, and type_spec. These methods are responsible for parsing new language constructs and constructing new AST nodes:

def block(self):
    """block : declarations compound_statement"""
    declaration_nodes = self.declarations()
    compound_statement_node = self.compound_statement()
    node = Block(declaration_nodes, compound_statement_node)
    return node

def declarations(self):
    """declarations : VAR (variable_declaration SEMI)+
                    | empty
    """
    declarations = []
    if self.current_token.type == VAR:
        self.eat(VAR)
        while self.current_token.type == ID:
            var_decl = self.variable_declaration()
            declarations.extend(var_decl)
            self.eat(SEMI)

    return declarations

def variable_declaration(self):
    """variable_declaration : ID (COMMA ID)* COLON type_spec"""
    var_nodes = [Var(self.current_token)]  # first ID
    self.eat(ID)

    while self.current_token.type == COMMA:
        self.eat(COMMA)
        var_nodes.append(Var(self.current_token))
        self.eat(ID)

    self.eat(COLON)

    type_node = self.type_spec()
    var_declarations = [
        VarDecl(var_node, type_node)
        for var_node in var_nodes
    ]
    return var_declarations

def type_spec(self):
    """type_spec : INTEGER
                 | REAL
    """
    token = self.current_token
    if self.current_token.type == INTEGER:
        self.eat(INTEGER)
    else:
        self.eat(REAL)
    node = Type(token)
    return node

We also need to update the program, term, and, factor methods to accommodate our grammar changes:

def program(self):
    """program : PROGRAM variable SEMI block DOT"""
    self.eat(PROGRAM)
    var_node = self.variable()
    prog_name = var_node.value
    self.eat(SEMI)
    block_node = self.block()
    program_node = Program(prog_name, block_node)
    self.eat(DOT)
    return program_node

def term(self):
    """term : factor ((MUL | INTEGER_DIV | FLOAT_DIV) factor)*"""
    node = self.factor()

    while self.current_token.type in (MUL, INTEGER_DIV, FLOAT_DIV):
        token = self.current_token
        if token.type == MUL:
            self.eat(MUL)
        elif token.type == INTEGER_DIV:
            self.eat(INTEGER_DIV)
        elif token.type == FLOAT_DIV:
            self.eat(FLOAT_DIV)

        node = BinOp(left=node, op=token, right=self.factor())

    return node

def factor(self):
    """factor : PLUS factor
              | MINUS factor
              | INTEGER_CONST
              | REAL_CONST
              | LPAREN expr RPAREN
              | variable
    """
    token = self.current_token
    if token.type == PLUS:
        self.eat(PLUS)
        node = UnaryOp(token, self.factor())
        return node
    elif token.type == MINUS:
        self.eat(MINUS)
        node = UnaryOp(token, self.factor())
        return node
    elif token.type == INTEGER_CONST:
        self.eat(INTEGER_CONST)
        return Num(token)
    elif token.type == REAL_CONST:
        self.eat(REAL_CONST)
        return Num(token)
    elif token.type == LPAREN:
        self.eat(LPAREN)
        node = self.expr()
        self.eat(RPAREN)
        return node
    else:
        node = self.variable()
        return node

Now, let’s see what the Abstract Syntax Tree looks like with the new nodes. Here is a small working Pascal program:

PROGRAM Part10AST;
VAR
   a, b : INTEGER;
   y    : REAL;

BEGIN {Part10AST}
   a := 2;
   b := 10 * a + 10 * a DIV 4;
   y := 20 / 7 + 3.14;
END.  {Part10AST}

Let’s generate an AST and visualize it with the genastdot.py:

$ python genastdot.py part10ast.pas > ast.dot && dot -Tpng -o ast.png ast.dot

In the picture you can see the new nodes that we have added.

Updating the Interpreter

We’re done with the lexer and parser changes. What’s left is to add new visitor methods to our Interpreter class. There will be four new methods to visit our new nodes:

visit_Program
visit_Block
visit_VarDecl
visit_Type

They are pretty straightforward. You can also see that the Interpreter does nothing with VarDecl and Type nodes:

def visit_Program(self, node):
    self.visit(node.block)

def visit_Block(self, node):
    for declaration in node.declarations:
        self.visit(declaration)
    self.visit(node.compound_statement)

def visit_VarDecl(self, node):
    # Do nothing
    pass

def visit_Type(self, node):
    # Do nothing
    pass

We also need to update the visit_BinOp method to properly interpret integer and float divisions:

def visit_BinOp(self, node):
    if node.op.type == PLUS:
        return self.visit(node.left) + self.visit(node.right)
    elif node.op.type == MINUS:
        return self.visit(node.left) - self.visit(node.right)
    elif node.op.type == MUL:
        return self.visit(node.left) * self.visit(node.right)
    elif node.op.type == INTEGER_DIV:
        return self.visit(node.left) // self.visit(node.right)
    elif node.op.type == FLOAT_DIV:
        return float(self.visit(node.left)) / float(self.visit(node.right))

Let’s sum up what we had to do to extend the Pascal interpreter in this article:

Add new rules to the grammar and update some existing rules
Add new tokens and supporting methods to the lexer, update and modify some existing methods
Add new AST nodes to the parser for new language constructs
Add new methods corresponding to the new grammar rules to our recursive-descent parser and update some existing methods
Add new visitor methods to the interpreter and update one existing visitor method

As a result of our changes we also got rid of some of the hacks I introduced in Part 9, namely:

Our interpreter can now handle the PROGRAM header
Variables can now be declared using the VAR keyword
The DIV keyword is used for integer division and a forward slash / is used for float division

If you haven’t done so yet, then, as an exercise, re-implement the interpreter in this article without looking at the source code and use part10.pas as your test input file.

That’s all for today. In the next article, I’ll talk in greater detail about symbol table management. Stay tuned and see you soon!

All articles in this series:

Let’s Build A Simple Interpreter. Part 9.

I remember when I was in university (a long time ago) and learning systems programming, I believed that the only “real” languages were Assembly and C. And Pascal was - how to put it nicely - a very high-level language used by application developers who didn’t want to know what was going on under the hood.

Little did I know back then that I would be writing almost everything in Python (and love every bit of it) to pay my bills and that I would also be writing an interpreter and compiler for Pascal for the reasons I stated in the very first article of the series.

These days, I consider myself a programming languages enthusiast, and I’m fascinated by all languages and their unique features. Having said that, I have to note that I enjoy using certain languages way more than others. I am biased and I’ll be the first one to admit that. :)

This is me before:

And now:

Okay, let’s get down to business. Here is what you’re going to learn today:

How to parse and interpret a Pascal program definition.
How to parse and interpret compound statements.
How to parse and interpret assignment statements, including variables.
A bit about symbol tables and how to store and lookup variables.

I’ll use the following sample Pascal-like program to introduce new concepts:

BEGIN
    BEGIN
        number := 2;
        a := number;
        b := 10 * a + 10 * number / 4;
        c := a - - b
    END;
    x := 11;
END.

You could say that that’s quite a jump from the command line interpreter you wrote so far by following the previous articles in the series, but it’s a jump that I hope will bring excitement. It’s not “just” a calculator anymore, we’re getting serious here, Pascal serious. :)

Let’s dive in and look at syntax diagrams for new language constructs and their corresponding grammar rules.

On your marks: Ready. Set. Go!

I’ll start with describing what a Pascal program is. A Pascal program consists of a compound statement that ends with a dot. Here is an example of a program:
```
“BEGIN  END.”
```
I have to note that this is not a complete program definition, and we’ll extend it later in the series.
What is a compound statement? A compound statement is a block marked with BEGIN and END that can contain a list (possibly empty) of statements including other compound statements. Every statement inside the compound statement, except for the last one, must terminate with a semicolon. The last statement in the block may or may not have a terminating semicolon. Here are some examples of valid compound statements:
```
“BEGIN END”
“BEGIN a := 5; x := 11 END”
“BEGIN a := 5; x := 11; END”
“BEGIN BEGIN a := 5 END; x := 11 END”
```
A statement list is a list of zero or more statements inside a compound statement. See above for some examples.
A statement can be a compound statement, an assignment statement, or it can be an empty statement.
An assignment statement is a variable followed by an ASSIGN token (two characters, ‘:’ and ‘=’) followed by an expression.
```
“a := 11”
“b := a + 9 - 5 * 2”
```
A variable is an identifier. We’ll use the ID token for variables. The value of the token will be a variable’s name like ‘a’, ‘number’, and so on. In the following code block ‘a’ and ‘b’ are variables:
```
“BEGIN a := 11; b := a + 9 - 5 * 2 END”
```
An empty statement represents a grammar rule with no further productions. We use the empty_statement grammar rule to indicate the end of the statement_list in the parser and also to allow for empty compound statements as in ‘BEGIN END’.
The factor rule is updated to handle variables.

Now let’s take a look at our complete grammar:

    program : compound_statement DOT

    compound_statement : BEGIN statement_list END

    statement_list : statement
                   | statement SEMI statement_list

    statement : compound_statement
              | assignment_statement
              | empty

    assignment_statement : variable ASSIGN expr

    empty :

    expr: term ((PLUS | MINUS) term)*

    term: factor ((MUL | DIV) factor)*

    factor : PLUS factor
           | MINUS factor
           | INTEGER
           | LPAREN expr RPAREN
           | variable

    variable: ID

You probably noticed that I didn’t use the star ‘*’ symbol in the compound_statement rule to represent zero or more repetitions, but instead explicitly specified the statement_list rule. This is another way to represent the ‘zero or more’ operation, and it will come in handy when we look at parser generators like PLY, later in the series. I also split the “(PLUS | MINUS) factor” sub-rule into two separate rules.

In order to support the updated grammar, we need to make a number of changes to our lexer, parser, and interpreter. Let’s go over those changes one by one.

Here is the summary of the changes in our lexer:

To support a Pascal program’s definition, compound statements, assignment statements, and variables, our lexer needs to return new tokens:
- BEGIN (to mark the beginning of a compound statement)
- END (to mark the end of the compound statement)
- DOT (a token for a dot character ‘.’ required by a Pascal program’s definition)
- ASSIGN (a token for a two character sequence ‘:=’). In Pascal, an assignment operator is different than in many other languages like C, Python, Java, Rust, or Go, where you would use single character ‘=’ to indicate assignment
- SEMI (a token for a semicolon character ‘;’ that is used to mark the end of a statement inside a compound statement)
- ID (A token for a valid identifier. Identifiers start with an alphabetical character followed by any number of alphanumerical characters)
Sometimes, in order to be able to differentiate between different tokens that start with the same character, (‘:’ vs ‘:=’ or ‘==’ vs ‘=>’ ) we need to peek into the input buffer without actually consuming the next character. For this particular purpose, I introduced a peek method that will help us tokenize assignment statements. The method is not strictly required, but I thought I would introduce it earlier in the series and it will also make the get_next_token method a bit cleaner. All it does is return the next character from the text buffer without incrementing the self.pos variable. Here is the method itself:
```
def peek(self):
    peek_pos = self.pos + 1
    if peek_pos > len(self.text) - 1:
        return None
    else:
        return self.text[peek_pos]
```
Because Pascal variables and reserved keywords are both identifiers, we will combine their handling into one method called _id. The way it works is that the lexer consumes a sequence of alphanumerical characters and then checks if the character sequence is a reserved word. If it is, it returns a pre-constructed token for that reserved keyword. And if it’s not a reserved keyword, it returns a new ID token whose value is the character string (lexeme). I bet at this point you think, “Gosh, just show me the code.” :) Here it is:
```
RESERVED_KEYWORDS = {
    'BEGIN': Token('BEGIN', 'BEGIN'),
    'END': Token('END', 'END'),
}

def _id(self):
    """Handle identifiers and reserved keywords"""
    result = ''
    while self.current_char is not None and self.current_char.isalnum():
        result += self.current_char
        self.advance()

    token = RESERVED_KEYWORDS.get(result, Token(ID, result))
    return token
```

And now let’s take a look at the changes in the main lexer method get_next_token:

def get_next_token(self):
    while self.current_char is not None:
        ...
        if self.current_char.isalpha():
            return self._id()

        if self.current_char == ':' and self.peek() == '=':
            self.advance()
            self.advance()
            return Token(ASSIGN, ':=')

        if self.current_char == ';':
            self.advance()
            return Token(SEMI, ';')

        if self.current_char == '.':
            self.advance()
            return Token(DOT, '.')
        ...

It’s time to see our shiny new lexer in all its glory and action. Download the source code from GitHub and launch your Python shell from the same directory where you saved the spi.py file:

>>> from spi import Lexer
>>> lexer = Lexer('BEGIN a := 2; END.')
>>> lexer.get_next_token()
Token(BEGIN, 'BEGIN')
>>> lexer.get_next_token()
Token(ID, 'a')
>>> lexer.get_next_token()
Token(ASSIGN, ':=')
>>> lexer.get_next_token()
Token(INTEGER, 2)
>>> lexer.get_next_token()
Token(SEMI, ';')
>>> lexer.get_next_token()
Token(END, 'END')
>>> lexer.get_next_token()
Token(DOT, '.')
>>> lexer.get_next_token()
Token(EOF, None)
>>>

Moving on to parser changes.

Here is the summary of changes in our parser:

Let’s start with new AST nodes:

Compound AST node represents a compound statement. It contains a list of statement nodes in its children variable.

class Compound(AST):
    """Represents a 'BEGIN ... END' block"""
    def __init__(self):
        self.children = []

Assign AST node represents an assignment statement. Its left variable is for storing a Var node and its right variable is for storing a node returned by the expr parser method:

class Assign(AST):
    def __init__(self, left, op, right):
        self.left = left
        self.token = self.op = op
        self.right = right

Var AST node (you guessed it) represents a variable. The self.value holds the variable’s name.

class Var(AST):
    """The Var node is constructed out of ID token."""
    def __init__(self, token):
        self.token = token
        self.value = token.value

NoOp node is used to represent an empty statement. For example ‘BEGIN END’ is a valid compound statement that has no statements.
```
class NoOp(AST):
    pass
```

As you remember, each rule from the grammar has a corresponding method in our recursive-descent parser. This time we’re adding seven new methods. These methods are responsible for parsing new language constructs and constructing new AST nodes. They are pretty straightforward:

def program(self):
    """program : compound_statement DOT"""
    node = self.compound_statement()
    self.eat(DOT)
    return node

def compound_statement(self):
    """
    compound_statement: BEGIN statement_list END
    """
    self.eat(BEGIN)
    nodes = self.statement_list()
    self.eat(END)

    root = Compound()
    for node in nodes:
        root.children.append(node)

    return root

def statement_list(self):
    """
    statement_list : statement
                   | statement SEMI statement_list
    """
    node = self.statement()

    results = [node]

    while self.current_token.type == SEMI:
        self.eat(SEMI)
        results.append(self.statement())

    if self.current_token.type == ID:
        self.error()

    return results

def statement(self):
    """
    statement : compound_statement
              | assignment_statement
              | empty
    """
    if self.current_token.type == BEGIN:
        node = self.compound_statement()
    elif self.current_token.type == ID:
        node = self.assignment_statement()
    else:
        node = self.empty()
    return node

def assignment_statement(self):
    """
    assignment_statement : variable ASSIGN expr
    """
    left = self.variable()
    token = self.current_token
    self.eat(ASSIGN)
    right = self.expr()
    node = Assign(left, token, right)
    return node

def variable(self):
    """
    variable : ID
    """
    node = Var(self.current_token)
    self.eat(ID)
    return node

def empty(self):
    """An empty production"""
    return NoOp()

We also need to update the existing factor method to parse variables:

def factor(self):
    """factor : PLUS  factor
              | MINUS factor
              | INTEGER
              | LPAREN expr RPAREN
              | variable
    """
    token = self.current_token
    if token.type == PLUS:
        self.eat(PLUS)
        node = UnaryOp(token, self.factor())
        return node
    ...
    else:
        node = self.variable()
        return node

The parser’s parse method is updated to start the parsing process by parsing a program definition:

def parse(self):
    node = self.program()
    if self.current_token.type != EOF:
        self.error()

    return node

Here is our sample program again:

BEGIN
    BEGIN
        number := 2;
        a := number;
        b := 10 * a + 10 * number / 4;
        c := a - - b
    END;
    x := 11;
END.

Let’s visualize it with genastdot.py (For brevity, when displaying a Var node, it just shows the node’s variable name and when displaying an Assign node it shows ‘:=’ instead of showing ‘Assign’ text):

$ python genastdot.py assignments.txt > ast.dot && dot -Tpng -o ast.png ast.dot

And finally, here are the required interpreter changes:

To interpret new AST nodes, we need to add corresponding visitor methods to the interpreter. There are four new visitor methods:

visit_Compound
visit_Assign
visit_Var
visit_NoOp

Compound and NoOp visitor methods are pretty straightforward. The visit_Compound method iterates over its children and visits each one in turn, and the visit_NoOp method does nothing.

def visit_Compound(self, node):
    for child in node.children:
        self.visit(child)

def visit_NoOp(self, node):
    pass

The Assign and Var visitor methods deserve a closer examination.

When we assign a value to a variable, we need to store that value somewhere for when we need it later, and that’s exactly what the visit_Assign method does:

def visit_Assign(self, node):
    var_name = node.left.value
    self.GLOBAL_SCOPE[var_name] = self.visit(node.right)

The method stores a key-value pair (a variable name and a value associated with the variable) in a symbol table GLOBAL_SCOPE. What is a symbol table? A symbol table is an abstract data type (ADT) for tracking various symbols in source code. The only symbol category we have right now is variables and we use the Python dictionary to implement the symbol table ADT. For now I’ll just say that the way the symbol table is used in this article is pretty “hacky”: it’s not a separate class with special methods but a simple Python dictionary and it also does double duty as a memory space. In future articles, I will be talking about symbol tables in much greater detail, and together we’ll also remove all the hacks.

Let’s take a look at an AST for the statement “a := 3;” and the symbol table before and after the visit_Assign method does its job:

Now let’s take a look at an AST for the statement “b := a + 7;”

As you can see, the right-hand side of the assignment statement - “a + 7” - references the variable ‘a’, so before we can evaluate the expression “a + 7” we need to find out what the value of ‘a’ is and that’s the responsibility of the visit_Var method:

def visit_Var(self, node):
    var_name = node.value
    val = self.GLOBAL_SCOPE.get(var_name)
    if val is None:
        raise NameError(repr(var_name))
    else:
        return val

When the method visits a Var node as in the above AST picture, it first gets the variable’s name and then uses that name as a key into the GLOBAL_SCOPE dictionary to get the variable’s value. If it can find the value, it returns it, if not - it raises a NameError exception. Here are the contents of the symbol table before evaluating the assignment statement “b := a + 7;”:

These are all the changes that we need to do today to make our interpreter tick. At the end of the main program, we simply print the contents of the symbol table GLOBAL_SCOPE to standard output.

Let’s take our updated interpreter for a drive both from a Python interactive shell and from the command line. Make sure that you downloaded both the source code for the interpreter and the assignments.txt file before testing:

Launch your Python shell:

$ python
>>> from spi import Lexer, Parser, Interpreter
>>> text = """\
... BEGIN
...
...     BEGIN
...         number := 2;
...         a := number;
...         b := 10 * a + 10 * number / 4;
...         c := a - - b
...     END;
...
...     x := 11;
... END.
... """
>>> lexer = Lexer(text)
>>> parser = Parser(lexer)
>>> interpreter = Interpreter(parser)
>>> interpreter.interpret()
>>> print(interpreter.GLOBAL_SCOPE)
{'a': 2, 'x': 11, 'c': 27, 'b': 25, 'number': 2}

And from the command line, using a source file as input to our interpreter:

$ python spi.py assignments.txt
{'a': 2, 'x': 11, 'c': 27, 'b': 25, 'number': 2}

If you haven’t tried it yet, try it now and see for yourself that the interpreter is doing its job properly.

Let’s sum up what you had to do to extend the Pascal interpreter in this article:

Add new rules to the grammar
Add new tokens and supporting methods to the lexer and update the get_next_token method
Add new AST nodes to the parser for new language constructs
Add new methods corresponding to the new grammar rules to our recursive-descent parser and update any existing methods, if necessary (factor method, I’m looking at you. :)
Add new visitor methods to the interpreter
Add a dictionary for storing variables and for looking them up

In this part I had to introduce a number of “hacks” that we’ll remove as we move forward with the series:

The program grammar rule is incomplete. We’ll extend it later with additional elements.
Pascal is a statically typed language, and you must declare a variable and its type before using it. But, as you saw, that was not the case in this article.
No type checking so far. It’s not a big deal at this point, but I just wanted to mention it explicitly. Once we add more types to our interpreter we’ll need to report an error when you try to add a string and an integer, for example.
A symbol table in this part is a simple Python dictionary that does double duty as a memory space. Worry not: symbol tables are such an important topic that I’ll have several articles dedicated just to them. And memory space (runtime management) is a topic of its own.
In our simple calculator from previous articles, we used a forward slash character ‘/’ for denoting integer division. In Pascal, though, you have to use a keyword div to specify integer division (See Exercise 1).
There is also one hack that I introduced on purpose so that you could fix it in Exercise 2: in Pascal all reserved keywords and identifiers are case insensitive, but the interpreter in this article treats them as case sensitive.

To keep you fit, here are new exercises for you:

Pascal variables and reserved keywords are case insensitive, unlike in many other programming languages, so BEGIN, begin, and BeGin they all refer to the same reserved keyword. Update the interpreter so that variables and reserved keywords are case insensitive. Use the following program to test it:
```
BEGIN

    BEGIN
        number := 2;
        a := NumBer;
        B := 10 * a + 10 * NUMBER / 4;
        c := a - - b
    end;

    x := 11;
END.
```
I mentioned in the “hacks” section before that our interpreter is using the forward slash character ‘/’ to denote integer division, but instead it should be using Pascal’s reserved keyword div for integer division. Update the interpreter to use the div keyword for integer division, thus eliminating one of the hacks.
Update the interpreter so that variables could also start with an underscore as in ‘_num := 5’.

That’s all for today. Stay tuned and see you soon.

Here is a list of books I recommend that will help you in your study of interpreters and compilers:

All articles in this series: