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# calculator.py
import re
import math
import operator
from typing import List, Dict, Optional
from contextlib import contextmanager
import signal
from functools import reduce
from fractions import Fraction
# TIMEOUT
@contextmanager
def timeout(duration: int = 1):
def handler(signum, frame):
raise TimeoutError(f"Timeout after {duration}s")
signal.signal(signal.SIGALRM, handler)
signal.alarm(duration)
try:
yield
finally:
signal.alarm(0)
# SAFE EVAL
def safe_eval(expr: str) -> Optional[float]:
expr = expr.strip().replace(",", "").replace("^", "**")
# SECURITY: BLOCK __class__, .., .x
if ".." in expr or "__" in expr:
return None
if re.search(r'\.\w', expr) and not re.search(r'\d\.', expr):
return None
# BLOCK GIANT EXPONENTS
if "**" in expr:
try:
_, exp_str = expr.split("**", 1)
exp = float(re.split(r'[\s+\-*/)]', exp_str)[0])
if abs(exp) > 20:
return None
except:
pass
# BLOCK SCIENTIFIC NOTATION OVERFLOW
sci_match = re.search(r'\d+e[+\-]?\d+', expr, re.IGNORECASE)
if sci_match:
try:
exp = int(re.search(r'e([+\-]?\d+)', sci_match.group(0), re.IGNORECASE).group(1))
if abs(exp) > 50:
return None
except:
return None
# FRACTION SIMPLIFICATION
if "/" in expr and not re.search(r'//', expr):
try:
parts = [p.strip() for p in expr.split("/", 1)]
if len(parts) == 2 and parts[0].isdigit() and parts[1].isdigit():
return float(Fraction(int(parts[0]), int(parts[1])))
except:
pass
# ALLOW % (modulo)
expr = expr.replace("%", " % ")
if not re.match(r'^[0-9+\-*/().%\s\*\^]+$', expr):
return None
try:
with timeout(1):
result = eval(expr, {"__builtins__": {}})
return float(result)
except:
return None
# EXTRACT << (GREEDY RIGHTMOST)
def extract_calc(text: str) -> Optional[str]:
match = re.search(r'<<([^>]*)(?:>>|$)', text)
if not match:
return None
expr = match.group(1).strip()
return expr if expr else None
# VARIABLE REPLACEMENT (longest first)
def substitute_variables(expr: str, context: Dict[str, float]) -> str:
for var in sorted(context.keys(), key=len, reverse=True):
expr = re.sub(rf'\b{re.escape(var)}\b', str(context[var]), expr)
return expr
# NESTED FUNCTION PARSER
def parse_nested_func(expr: str, allowed_funcs: set = None) -> Optional[float]:
if allowed_funcs is None:
allowed_funcs = {"sqrt", "log", "pow", "max", "min", "abs", "sin", "cos", "tan", "exp"}
def eval_inner(inner: str) -> float:
inner = inner.strip()
if inner.startswith("(") and inner.endswith(")"):
inner = inner[1:-1]
return parse_nested_func(inner, allowed_funcs) or safe_eval(inner) or 0.0
match = re.match(r'^([a-zA-Z_]\w*)\((.+)\)$', expr.strip())
if not match:
return None
func_name, args_str = match.groups()
if func_name not in allowed_funcs:
return None
# Split top-level commas
args = []
depth = 0
current = ""
for char in args_str:
if char == "," and depth == 0:
args.append(current)
current = ""
else:
current += char
if char == "(": depth += 1
if char == ")": depth -= 1
if current:
args.append(current)
try:
arg_vals = [eval_inner(a) for a in args]
# BLOCK GIANT pow() AND exp()
if func_name == "pow" and len(arg_vals) >= 2 and abs(arg_vals[1]) > 20:
return None
if func_name == "exp" and arg_vals and abs(arg_vals[0]) > 20:
return None
func_map = {
"sqrt": lambda x: math.sqrt(x[0]),
"log": lambda x: math.log(x[0], x[1]) if len(x) > 1 else math.log(x[0]),
"pow": lambda x: x[0] ** x[1],
"max": lambda x: max(x),
"min": lambda x: min(x),
"abs": lambda x: abs(x[0]),
"sin": lambda x: math.sin(x[0]),
"cos": lambda x: math.cos(x[0]),
"tan": lambda x: math.tan(x[0]),
"exp": lambda x: math.exp(x[0]),
}
return func_map[func_name](arg_vals)
except:
return None
# === SEQUENCE + RANGE (NESTED) ===
def parse_range(range_str: str) -> List[float]:
match = re.match(r'(-?\d+)\.\.(-?\d+)', range_str.strip())
if not match:
return []
start, end = map(int, match.groups())
step = 1 if start <= end else -1
return list(range(start, end + step, step))
def evaluate_sequence(expr: str) -> Optional[float]:
match = re.match(r'(sum|prod|mean)\((.*)\)', expr.replace(" ", ""))
if not match:
return None
op, args_str = match.groups()
def parse_arg(arg: str):
arg = arg.strip()
if ".." in arg:
return parse_range(arg)
val = parse_nested_func(arg) or safe_eval(arg)
return [val] if val is not None else []
args = []
depth = 0
current = ""
for char in args_str:
if char == "," and depth == 0:
args.extend(parse_arg(current))
current = ""
else:
current += char
if char == "(": depth += 1
if char == ")": depth -= 1
if current:
args.extend(parse_arg(current))
if not args:
return None
if op == "sum": return sum(args)
if op == "prod": return reduce(operator.mul, args, 1)
if op == "mean": return sum(args) / len(args)
return None
# CALCULATOR
def calculate(expr: str, context: Dict[str, float] = None) -> Optional[str]:
if context is None:
context = {}
expr = substitute_variables(expr, context)
seq = evaluate_sequence(expr)
if seq is not None:
return f"{expr}={seq}>>"
func = parse_nested_func(expr)
if func is not None:
return f"{expr}={func}>>"
basic = safe_eval(expr)
if basic is not None:
return f"{expr}={basic}>>"
return None
# PUBLIC API
def use_calculator(text: str, context: Dict[str, float] = None) -> Optional[str]:
expr = extract_calc(text)
if not expr:
return None
return calculate(expr, context)
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