{-# OPTIONS_GHC -Wno-unused-imports -Wno-unused-top-binds #-}
import Control.Monad
import Data.Maybe
import qualified Data.ByteString.Char8 as BS
import Control.Monad.ST             
import Data.Ix
import Data.Array (Array)
import Data.Array.IArray
import Data.Array.IO             
import Data.Array.MArray          
import Data.Array.ST                
import Data.Array.Unboxed (UArray)
import Data.Char
import Data.List as L
import Data.Foldable
import Data.Function
import Control.Exception
import Data.Array.Base (STUArray(STUArray), UArray (UArray))
import Data.Array.IO.Internals (IOUArray(IOUArray))
import Data.Ord
import GHC.Float

toBinary = toXnary 2

myZip xs ys m
  | nx && ny = m 
  | otherwise = myZip tx ty (z' : m)
  where
    nx = null xs
    ny = null ys
    z' = (x', y')
    x' = if nx then '0' else head xs
    y' = if ny then '0' else head ys
    tx = if nx then [] else tail xs
    ty = if ny then [] else tail ys


f :: (Char, Char) -> Int
f ('1', '1') = 2
f ('0', '0') = 1
f ('1', '0') = 0
f ('0', '1') = 1

main :: IO ()
main = do
  [a, b] <- getIntList
  let 
    a' = reverse $ toBinary a
    b' = reverse $ toBinary b
    zs = myZip a' b' []
    ans = product $ map f zs
  print ans



--library--------------
modulus :: Int
modulus = 10 ^ 9 + 7
addMod, subMod, mulMod :: Int -> Int -> Int
addMod x y = (x + y) `mod` modulus
subMod x y = (x - y) `mod` modulus
mulMod x y = (x * y) `mod` modulus
tuplify2 :: [b] -> (b, b)
tuplify2 (x:y:_) = (x,y)
tuplify2 _ = undefined

readInt :: BS.ByteString -> Int
readInt = fst . fromJust . BS.readInt
readIntTuple :: BS.ByteString -> (Int, Int)
readIntTuple = tuplify2 . map readInt . BS.words
readIntList :: BS.ByteString -> [Int]
readIntList = map readInt . BS.words

getInt :: IO Int
getInt = readInt <$> BS.getLine
getIntList :: IO [Int]
getIntList = readIntList <$> BS.getLine
getIntListX :: IO [Int]
getIntListX = readIntList <$> BS.getContents
getIntNList :: Integral a => a -> IO [[Int]]
getIntNList n = map readIntList <$> replicateM (fromIntegral n) BS.getLine
getIntMatrix :: IO [[Int]]
getIntMatrix = map readIntList . BS.lines <$> BS.getContents
getIntTuple :: IO (Int, Int)
getIntTuple = readIntTuple <$> BS.getLine
getIntNTuples :: Integral a => a -> IO [(Int, Int)]
getIntNTuples n = map readIntTuple <$> replicateM (fromIntegral n) BS.getLine
getIntTuples :: IO [(Int, Int)]
getIntTuples = map readIntTuple . BS.lines <$> BS.getContents
getIntMatArr :: Int -> Int -> IO (UArray (Int, Int) Int)
getIntMatArr h w = listArray ((1, 1), (h, w)) . concat <$> getIntNList h

yn :: Bool -> IO ()
yn bl = putStrLn $ if bl then "Yes" else "No"
putInts :: [Int] -> IO ()
putInts x = putStrLn $ unwords $ map show x
nubOrd :: Eq a => Ord a => [a] -> [a]
nubOrd = map head.group.sort
toXnary :: (Show a, Integral a) => a -> a -> String 
toXnary x n = concatMap show $ reverse $ help x n
  where
    help x n
      | n == 0 = []
      | otherwise = mod n x : help x (div n x)