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abstract_syntax_tree.py
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import math
variable = {}
class EBinary:
def __init__(self, operand_left, operator, operand_right):
self.operand_left = operand_left
self.operator = operator
self.operand_right = operand_right
self.type = "Binary"
class ENumber:
def __init__(self, value):
self.value = value
self.type = "Number"
class EUnary:
def __init__(self, operator, operand):
self.operator = operator
self.operand = operand
self.type = "Unary"
class EVariable:
def __init__(self, name):
self.name = name
self.type = "Variable"
class EParentheses:
def __init__(self, expression):
self.expression = expression
self.type = "Parentheses"
class EFunction:
def __init__(self, name, arguments):
self.name = name
self.arguments = arguments
self.type = "Function"
class EEmpty:
def __init__(self):
self.type = "Empty"
class EAssignment:
def __init__(self, name, expression):
self.name = name
self.expression = expression
self.type = "Assignment"
class Token:
def __init__(self, value, type, line, column):
self.value = value
self.type = type
self.line = line
self.column = column
class Parser:
def __init__(self, tokens):
self.tokens = tokens
self.index = 0
self.next_token = tokens[self.index]
def peek(self, type):
return self.next_token.type == type
def consume(self, type):
if self.peek(type):
self.index += 1
self.next_token = self.tokens[self.index]
return self.tokens[self.index - 1]
else:
raise SyntaxError("Expected token of type " + type + " at line " + str(self.next_token.line) + " column " + str(self.next_token.column)+ " but got " + self.next_token.type + " instead.")
def parseVS(self):
e = EEmpty()
while True:
if self.peek("EOF"):
return e
elif self.peek("VARIABLE"):
var = self.consume("VARIABLE")
self.consume("EQUAL")
exp = self.parseE()
e = EAssignment(var.value, exp)
variable[var.value] = exp
if not self.peek("NEWLINE"):
if self.peek("EOF"):
return e
raise SyntaxError("Expected token of type NEWLINE at line " + str(self.next_token.line) + " column " + str(self.next_token.column) + " but got " + self.next_token.type + " instead.")
else:
break
return e
def parsePS(self):
e = EEmpty()
while True:
if self.peek("EOF"):
return e
elif self.peek("PRINT"):
self.consume("PRINT")
e = self.parseE()
if not self.peek("NEWLINE"):
if self.peek("EOF"):
return e
raise SyntaxError("Expected token of type NEWLINE at line " + str(self.next_token.line) + " column " + str(self.next_token.column) + " but got " + self.next_token.type + " instead.")
else:
break
return e
def parseS(self):
if self.peek("VARIABLE"):
return self.parseVS()
elif self.peek("PRINT"):
return self.parsePS()
elif self.peek("NEWLINE") or self.peek("EOF"):
return EEmpty()
else:
raise SyntaxError("Expected token of type VARIABLE or PRINT at line " + str(self.next_token.line) + " column " + str(self.next_token.column))
def parseE(self):
e = self.parseT()
while True:
if self.peek("EOF"):
return e
elif self.peek("SUM"):
self.consume("SUM")
if not self.peek("NUM") and not self.peek("VARIABLE") and not self.peek("PARENTESES_L") and not self.peek("FUNCTION"):
raise SyntaxError("Expected token of type NUMBER, VARIABLE, PARENTESES_L or FUNCTION at line " + str(self.next_token.line) + " column " + str(self.next_token.column))
e = EBinary(e, "+", self.parseT())
elif self.peek("SUB"):
self.consume("SUB")
if not self.peek("NUM") and not self.peek("VARIABLE") and not self.peek("PARENTESES_L") and not self.peek("FUNCTION"):
raise SyntaxError("Expected token of type NUMBER, VARIABLE, PARENTESES_L or FUNCTION at line " + str(self.next_token.line) + " column " + str(self.next_token.column))
e = EBinary(e, "-", self.parseT())
else:
break
return e
def parseT(self):
e = self.parseF()
while True:
if self.peek("EOF"):
return e
elif self.peek("MULT"):
self.consume("MULT")
if not self.peek("NUM") and not self.peek("VARIABLE") and not self.peek("PARENTESES_L") and not self.peek("FUNCTION"):
raise SyntaxError("Expected token of type NUMBER, VARIABLE, PARENTESES_L or FUNCTION at line " + str(self.next_token.line) + " column " + str(self.next_token.column))
e = EBinary(e, "*", self.parseF())
elif self.peek("DIV"):
self.consume("DIV")
if not self.peek("NUM") and not self.peek("VARIABLE") and not self.peek("PARENTESES_L") and not self.peek("FUNCTION"):
raise SyntaxError("Expected token of type NUMBER, VARIABLE, PARENTESES_L or FUNCTION at line " + str(self.next_token.line) + " column " + str(self.next_token.column))
e = EBinary(e, "/", self.parseF())
else:
break
return e
def parseF(self):
if self.peek("NUM"):
n = self.consume("NUM")
return ENumber(int(n.value))
elif self.peek("VARIABLE"):
v = self.consume("VARIABLE")
return EVariable(v.value)
elif self.peek("PARENTESES_L"):
self.consume("PARENTESES_L")
e = self.parseE()
self.consume("PARENTESES_R")
return EParentheses(e)
elif self.peek("SUB"):
self.consume("SUB")
e = self.parseF()
return EUnary("-", e)
elif self.peek("FUNCTION"):
function = self.consume("FUNCTION").value
self.consume("PARENTESES_L")
e = self.parseE()
self.consume("PARENTESES_R")
return EFunction(function, [e])
def evaluate_expression(expression, variables = variable):
match expression.type:
case "Binary":
match expression.operator:
case "+":
return evaluate_expression(expression.operand_left, variables) + evaluate_expression(expression.operand_right, variables)
case "-":
return evaluate_expression(expression.operand_left, variables) - evaluate_expression(expression.operand_right, variables)
case "*":
return evaluate_expression(expression.operand_left, variables) * evaluate_expression(expression.operand_right, variables)
case "/":
return evaluate_expression(expression.operand_left, variables) / evaluate_expression(expression.operand_right, variables)
case _:
raise Exception("Invalid operator, got " + expression.operator + " instead.")
case "Number":
return expression.value
case "Unary":
if expression.operator == "+":
return +evaluate_expression(expression.operand, variables)
elif expression.operator == "-":
return -evaluate_expression(expression.operand, variables)
else:
raise Exception("Invalid unary, got " + expression.operator + " instead.")
case "Variable":
assert(expression.name in variables)
return evaluate_expression(variables[expression.name], variables)
case "Parentheses":
return evaluate_expression(expression.expression, variables)
case "Function":
match expression.name:
case "sin":
return math.sin(evaluate_expression(expression.arguments[0], variables))
case "cos":
return math.cos(evaluate_expression(expression.arguments[0], variables))
case "tan":
return math.tan(evaluate_expression(expression.arguments[0], variables))
case "sqrt":
if evaluate_expression(expression.arguments[0], variables) < 0:
raise ValueError("Square root of negative number")
return math.sqrt(evaluate_expression(expression.arguments[0], variables))
case _:
raise Exception("Invalid function, got " + expression.name + " instead.")
case "Empty":
return 0
case "Assignment":
return evaluate_expression(expression.expression, variables)
case _:
raise Exception("Invalid expression type, got " + expression.type + " instead.")
def expression_to_string(expression, variables = variable):
match expression.type:
case "Binary":
return "(" + expression_to_string(expression.operand_left, variables) + " " + expression.operator + " " + expression_to_string(expression.operand_right, variables) + ")"
case "Number":
return str(expression.value)
case "Unary":
return "(" + expression.operator + expression_to_string(expression.operand, variables) + ")"
case "Variable":
return expression_to_string(variables[expression.name], variables)
case "Parentheses":
return "(" + expression_to_string(expression.expression, variables) + ")"
case "Function":
return expression.name + "(" + ", ".join([expression_to_string(argument, variables) for argument in expression.arguments]) + ")"
case "Empty":
return ""
case "Assignment":
return expression.name + " = " + expression_to_string(expression.expression, variables)
case _:
raise Exception("Invalid expression type, got " + expression.type + " instead.")
def optimize_expression(expression, variables = variable):
match expression.type:
case "Unary":
if expression.operator == "-":
if expression.operand.type == "Unary" and expression.operand.operator == "-":
return optimize_expression(expression.operand.operand, variables)
return EUnary(expression.operator, optimize_expression(expression.operand, variables))
case "Binary":
if expression.operator == "+":
if expression.operand_left.type == "Number" and expression.operand_left.value == 0:
return optimize_expression(expression.operand_right, variables)
elif expression.operand_right.type == "Number" and expression.operand_right.value == 0:
return optimize_expression(expression.operand_left, variables)
return EBinary(optimize_expression(expression.operand_left, variables), expression.operator, optimize_expression(expression.operand_right, variables))
case "Number":
return expression
case "Variable":
return optimize_expression(variables[expression.name], variables)
case "Parentheses":
return EParentheses(optimize_expression(expression.expression, variables))
case "Function":
return EFunction(expression.name, [optimize_expression(argument, variables) for argument in expression.arguments])
case "Empty":
return EEmpty()
case "Assignment":
return EAssignment(expression.name, optimize_expression(expression.expression, variables))
case _:
raise Exception("Invalid expression type, got " + expression.type + " instead.")