overhauled calc module

README.md

@@ -3,4 +3,4 @@ It's like Sopel, except rewritten from scratch using Twisted as a base and over
 
 ## Requirements  
 Python 3.6+  
-Python packages: `twisted python-dateutil requests bs4 wolframalpha emoji pillow ipython numpy numpngw`  
+Python packages: `twisted python-dateutil requests bs4 wolframalpha emoji pillow ipython numpy numpngw numexpr`  

modules/calc.py

@@ -2,30 +2,44 @@
 """
 A basic calculator and python interpreter application.
 """
-import sys
+import multiprocessing
 
+import numpy
+import numexpr
 import requests
 
 from module import commands, example
-from tools.calculation import eval_equation
 
 BASE_TUMBOLIA_URI = 'https://tumbolia-two.appspot.com/'
 
 @commands('calc', 'c')
 @example('.c 5 + 3', '8')
 def c(bot, trigger):
-	"""Evaluate some calculation."""
+	"""Evaluates a mathematical expression."""
 	if len(trigger.args) < 2:
 		return bot.reply("Nothing to calculate.")
-	eqn = ' '.join(trigger.args[1:])
-	try:
-		result = eval_equation(eqn)
-		result = "{:.10g}".format(result)
-	except ZeroDivisionError:
-		result = "Division by zero is not supported in this universe."
-	except Exception as e:
-		result = "{error}: {msg}".format(error=type(e), msg=e)
-	bot.reply(result)
+	expr = ' '.join(trigger.args[1:])
+
+	def worker(expr, return_dict):
+		with numpy.errstate(all='ignore'):
+			try:
+				value = numexpr.evaluate(expr, local_dict={}, global_dict={})
+				value = value.item()
+			except:
+				value = "Error. The expression was not understood."
+			return_dict['value'] = value
+
+	with multiprocessing.Manager() as manager:
+		d = manager.dict()
+		proc = multiprocessing.Process(target=worker, args=(expr, d))
+		proc.start()
+		proc.join(1)
+		if proc.is_alive():
+			proc.kill()
+			proc.join()
+			proc.close()
+			return bot.reply("Calculation timed out.")
+		bot.reply(str(d['value']))
 
 
 @commands('py')
@@ -42,7 +56,6 @@ def py(bot, trigger):
 	answer = res.text
 	answer = answer[:2000]
 	if answer:
-		#bot.msg can potentially lead to 3rd party commands triggering.
 		bot.msg(answer, length=300)
 	else:
 		bot.reply('Sorry, no result.')

tools/calculation.py

@@ -1,197 +0,0 @@
-#!/usr/bin/env python3
-"""
-Tools to help safely do calculations from user input.
-"""
-import time
-import numbers
-import operator
-import ast
-
-__all__ = ['eval_equation']
-
-
-class ExpressionEvaluator:
-	"""
-	A generic class for evaluating limited forms of Python expressions.
-
-	Instances can overwrite binary_ops and unary_ops attributes with dicts of
-	the form {ast.Node, function}. When the ast.Node being used as key is
-	found, it will be evaluated using the given function.
-	"""
-
-	class Error(Exception):
-		pass
-
-	def __init__(self, bin_ops=None, unary_ops=None):
-		self.binary_ops = bin_ops or {}
-		self.unary_ops = unary_ops or {}
-
-	def __call__(self, expression_str, timeout=5.0):
-		"""
-		Evaluate a python expression and return the result.
-
-		Raises:
-			SyntaxError: If the given expression_str is not a valid python
-				statement.
-			ExpressionEvaluator.Error: If the instance of ExpressionEvaluator
-				does not have a handler for the ast.Node.
-		"""
-		ast_expression = ast.parse(expression_str, mode='eval')
-		return self._eval_node(ast_expression.body, time.time() + timeout)
-
-	def _eval_node(self, node, timeout):
-		"""
-		Recursively evaluate the given ast.Node.
-
-		Uses self.binary_ops and self.unary_ops for the implementation.
-
-		A subclass could overwrite this to handle more nodes, calling it only
-		for nodes it does not implement it self.
-
-		Raises:
-			ExpressionEvaluator.Error: If it can't handle the ast.Node.
-		"""
-		if isinstance(node, ast.Num):
-			return node.n
-
-		elif (isinstance(node, ast.BinOp) and
-				type(node.op) in self.binary_ops):
-			left = self._eval_node(node.left, timeout)
-			right = self._eval_node(node.right, timeout)
-			if time.time() > timeout:
-				raise ExpressionEvaluator.Error(
-					"Time for evaluating expression ran out.")
-			return self.binary_ops[type(node.op)](left, right)
-
-		elif (isinstance(node, ast.UnaryOp) and
-				type(node.op) in self.unary_ops):
-			operand = self._eval_node(node.operand, timeout)
-			if time.time() > timeout:
-				raise ExpressionEvaluator.Error(
-					"Time for evaluating expression ran out.")
-			return self.unary_ops[type(node.op)](operand)
-
-		raise ExpressionEvaluator.Error(
-			"Ast.Node '%s' not implemented." % (type(node).__name__,))
-
-
-def guarded_mul(left, right):
-	"""Decorate a function to raise an error for values > limit."""
-	# Only handle ints because floats will overflow anyway.
-	if not isinstance(left, numbers.Integral):
-		pass
-	elif not isinstance(right, numbers.Integral):
-		pass
-	elif left in (0, 1) or right in (0, 1):
-		# Ignore trivial cases.
-		pass
-	elif left.bit_length() + right.bit_length() > 664386:
-		# 664386 is the number of bits (10**100000)**2 has, which is instant on
-		# my laptop, while (10**1000000)**2 has a noticeable delay. It could
-		# certainly be improved.
-		raise ValueError(
-			"Value is too large to be handled in limited time and memory.")
-
-	return operator.mul(left, right)
-
-
-def pow_complexity(num, exp):
-	"""
-	Estimate the worst case time pow(num, exp) takes to calculate.
-
-	This function is based on experimetal data from the time it takes to
-	calculate "num**exp" on laptop with i7-2670QM processor on a 32 bit
-	CPython 2.7.6 interpreter on Windows.
-
-	It tries to implement this surface: x=exp, y=num
-		   1e5    2e5    3e5    4e5    5e5    6e5    7e5    8e5    9e5
-	e1    0.03   0.09   0.16   0.25   0.35   0.46   0.60   0.73   0.88
-	e2    0.08   0.24   0.46   0.73   1.03   1.40   1.80   2.21   2.63
-	e3    0.15   0.46   0.87   1.39   1.99   2.63   3.35   4.18   5.15
-	e4    0.24   0.73   1.39   2.20   3.11   4.18   5.39   6.59   7.88
-	e5    0.34   1.03   2.00   3.12   4.48   5.97   7.56   9.37  11.34
-	e6    0.46   1.39   2.62   4.16   5.97   7.86  10.09  12.56  15.39
-	e7    0.60   1.79   3.34   5.39   7.60  10.16  13.00  16.23  19.44
-	e8    0.73   2.20   4.18   6.60   9.37  12.60  16.26  19.83  23.70
-	e9    0.87   2.62   5.15   7.93  11.34  15.44  19.40  23.66  28.58
-
-	For powers of 2 it tries to implement this surface:
-		  1e7    2e7    3e7    4e7    5e7    6e7    7e7    8e7    9e7
-	1    0.00   0.00   0.00   0.00   0.00   0.00   0.00   0.00   0.00
-	2    0.21   0.44   0.71   0.92   1.20   1.49   1.66   1.95   2.23
-	4    0.43   0.91   1.49   1.96   2.50   3.13   3.54   4.10   4.77
-	8    0.70   1.50   2.24   3.16   3.83   4.66   5.58   6.56   7.67
-
-	The function number were selected by starting with the theoretical
-	complexity of exp * log2(num)**2 and fiddling with the exponents
-	untill it more or less matched with the table.
-
-	Because this function is based on a limited set of data it might
-	not give accurate results outside these boundaries. The results
-	derived from large num and exp were quite accurate for small num
-	and very large exp though, except when num was a power of 2.
-	"""
-	if num in (0, 1) or exp in (0, 1):
-		return 0
-	elif (num & (num - 1)) == 0:
-		# For powers of 2 the scaling is a bit different.
-		return exp ** 1.092 * num.bit_length() ** 1.65 / 623212911.121
-	else:
-		return exp ** 1.590 * num.bit_length() ** 1.73 / 36864057619.3
-
-
-def guarded_pow(left, right):
-	# Only handle ints because floats will overflow anyway.
-	if not isinstance(left, numbers.Integral):
-		pass
-	elif not isinstance(right, numbers.Integral):
-		pass
-	elif pow_complexity(left, right) < 0.5:
-		# Value 0.5 is arbitary and based on a estimated runtime of 0.5s
-		# on a fairly decent laptop processor.
-		pass
-	else:
-		raise ValueError("Pow expression too complex to calculate.")
-
-	return operator.pow(left, right)
-
-
-class EquationEvaluator(ExpressionEvaluator):
-	__bin_ops = {
-		ast.Add: operator.add,
-		ast.Sub: operator.sub,
-		ast.Mult: guarded_mul,
-		ast.Div: operator.truediv,
-		ast.Pow: guarded_pow,
-		ast.Mod: operator.mod,
-		ast.FloorDiv: operator.floordiv,
-		ast.BitXor: guarded_pow
-	}
-	__unary_ops = {
-		ast.USub: operator.neg,
-		ast.UAdd: operator.pos,
-	}
-
-	def __init__(self):
-		ExpressionEvaluator.__init__(
-			self,
-			bin_ops=self.__bin_ops,
-			unary_ops=self.__unary_ops
-		)
-
-	def __call__(self, expression_str):
-		result = ExpressionEvaluator.__call__(self, expression_str)
-
-		# This wrapper is here so additional sanity checks could be done
-		# on the result of the eval, but currently none are done.
-
-		return result
-
-
-eval_equation = EquationEvaluator()
-"""
-Evaluates a Python equation expression and returns the result.
-
-Supports addition (+), subtraction (-), multiplication (*), division (/),
-power (**) and modulo (%).
-"""