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kaleidoscope_parser.py
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kaleidoscope_parser.py
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from AST import NumberExpression, VariableExpression, FunctionCallExpression, PrototypeNode, FunctionNode, \
BinaryOperatorExpression, IfExpression, ForExpression
from kaleidoscope_lexer import CharacterToken, NumberToken, IdentifierToken, EOFToken, DefToken, ExternToken, Lexer, \
OpenParenthesisToken, ClosedParenthesisToken, IfToken, ThenToken, ElseToken, ForToken, AssignToken, CommaToken, \
InToken
from operators import Operators
class ParserException(Exception):
pass
class Parser:
def __init__(self):
self.tokens = None
self.current = None
self.operators_precendence = Operators()
def next(self):
self.current = next(self.tokens)
def parse_number_expression(self):
"""
numberexpr ::= number
"""
result = NumberExpression(self.current.value)
self.next()
return result
def parse_parenthesis_expression(self):
"""
parenexpr ::= '(' expression ')'
"""
self.next() # consume '('
contents = self.parse_expression()
if self.current != ClosedParenthesisToken():
raise ParserException("Expected ')', got " + str(self.current))
self.next() # consume ')'
return contents
def parse_expression(self):
"""
expression ::= primary binoprhs
"""
left = self.parse_primary_expression()
return self.parse_binary_op(left, 0)
def parse_binary_op(self, left, left_precedence):
"""
binoprhs ::= (operator primary)*
"""
while True:
precedence = self.operators_precendence.get(self.current)
if precedence < left_precedence:
return left
operator = self.current.char
self.next()
right = self.parse_primary_expression()
next_precedence = self.operators_precendence.get(self.current)
if precedence < next_precedence:
right = self.parse_binary_op(right, precedence + 1)
left = BinaryOperatorExpression(operator, left, right)
def parse_if_expression(self):
"""
ifexpr ::= 'if' expression 'then' expression 'else' expression
"""
self.next()
condition = self.parse_expression()
if not isinstance(self.current, ThenToken):
raise ParserException("Expected 'then' after if, got " + str(self.current))
self.next()
then_expression = self.parse_expression()
if not isinstance(self.current, ElseToken):
raise ParserException("Expected 'else' after if, got " + str(self.current))
self.next()
else_expression = self.parse_expression()
return IfExpression(condition, then_expression, else_expression)
def parse_for_expression(self):
"""
forexpr ::= 'for' identifier '=' expr ',' expr (',' expr)? 'in' expression
"""
self.next()
if not isinstance(self.current, IdentifierToken):
raise ParserException("Expected identifier after 'for', got " + str(self.current))
loop_variable = self.current.name
self.next()
if self.current != AssignToken():
raise ParserException("Expected '=' after variable in for, got " + str(self.current))
self.next()
start = self.parse_expression()
if self.current != CommaToken():
raise ParserException("Expected ',' after variable start value in for, got " + str(self.current))
self.next()
end = self.parse_expression()
if self.current == CommaToken():
self.next()
step = self.parse_expression()
else:
step = None
if not isinstance(self.current, InToken):
raise ParserException("Expected 'in' after the loop, got " + str(self.current))
self.next()
body = self.parse_expression()
return ForExpression(loop_variable, start, end, step, body)
def parse_identifier_expression(self):
"""
identifierexpr ::= identifier | identifier '(' expression* ')'
"""
identifier_name = self.current.name
self.next()
if self.current != OpenParenthesisToken():
return VariableExpression(identifier_name)
self.next() # consume '('
arguments = []
if self.current != ClosedParenthesisToken():
while True:
arguments.append(self.parse_expression())
if self.current == ClosedParenthesisToken():
break
if self.current != CommaToken():
raise ParserException("Expected ',' or ')' in the argument list")
self.next()
self.next() # consume ')'
return FunctionCallExpression(identifier_name, arguments)
def parse_primary_expression(self):
"""
primary ::= identifierexpr | numberexpr | parenexpr | ifexpression | forexpression
"""
if isinstance(self.current, IdentifierToken):
return self.parse_identifier_expression()
elif isinstance(self.current, NumberToken):
return self.parse_number_expression()
elif isinstance(self.current, IfToken):
return self.parse_if_expression()
elif isinstance(self.current, ForToken):
return self.parse_for_expression()
elif self.current == OpenParenthesisToken():
return self.parse_parenthesis_expression()
else:
raise ParserException("Unknown token when parsing primary: " + str(self.current))
def parse_prototype_expression(self):
"""
prototype ::= id '(' id* ')'
"""
if not isinstance(self.current, IdentifierToken):
raise ParserException("Expected function name in prototype")
function_name = self.current.name
self.next()
if self.current != OpenParenthesisToken():
raise ParserException("Expected '(' in function prototype")
self.next()
argument_names = []
while isinstance(self.current, IdentifierToken):
argument_names.append(self.current.name)
self.next()
if self.current != ClosedParenthesisToken():
raise ParserException("Expected ')' in function prototype")
self.next()
return PrototypeNode(function_name, argument_names)
def parse_definition(self):
"""
definition ::= 'def' prototype expression
"""
self.next()
prototype = self.parse_prototype_expression()
expression = self.parse_expression()
return FunctionNode(prototype, expression)
def parse_external(self):
"""
external ::= 'extern' prototype
"""
self.next()
return self.parse_prototype_expression()
def parse_toplevel_expression(self):
"""
toplevelexpr ::= expression
"""
expression = self.parse_expression()
return FunctionNode.create_anonymous(expression)
def parse(self, string):
"""
top ::= definition | external | expression | EOF
"""
lexer = Lexer()
self.tokens = lexer.tokenize(string)
self.next()
if isinstance(self.current, EOFToken):
pass
elif isinstance(self.current, DefToken):
print('Parsed a function definition.')
return self.parse_definition()
elif isinstance(self.current, ExternToken):
print('Parsed an extern.')
return self.parse_external()
else:
print('Parsed a top-level expression.')
return self.parse_toplevel_expression()
def _flatten(self, ast):
if isinstance(ast, NumberExpression):
return ['Number', ast.value]
elif isinstance(ast, VariableExpression):
return ['Variable', ast.name]
elif isinstance(ast, BinaryOperatorExpression):
return ['Binop', ast.operator,
self._flatten(ast.left), self._flatten(ast.right)]
elif isinstance(ast, FunctionCallExpression):
args = [self._flatten(arg) for arg in ast.arguments]
return ['Call', ast.function, args]
elif isinstance(ast, PrototypeNode):
return ['Prototype', ast.name, ' '.join(ast.arguments)]
elif isinstance(ast, FunctionNode):
return ['Function',
self._flatten(ast.prototype), self._flatten(ast.body)]
else:
raise TypeError('unknown type in _flatten: {0}'.format(type(ast)))