{-# LANGUAGE BangPatterns       #-}
{-# LANGUAGE NumericUnderscores #-}

import           Control.Monad
import           Control.Monad.Cont
import           Control.Monad.ST
import           Data.IORef
import qualified Data.Vector.Fusion.Stream.Monadic as VFSM
import qualified Data.Vector.Unboxed               as VU
import qualified Data.Vector.Unboxed.Mutable       as VUM

modulus :: Int
modulus = 1_000_000_007
{-# INLINE modulus #-}

main :: IO ()
main = do
  n <- readLn :: IO Int
  a <- VUM.replicate (600 * 600) 0 :: IO (VUM.IOVector Int)
  b <- VUM.replicate (600 * 600) 0 :: IO (VUM.IOVector Int)
  c <- VUM.replicate (600 * 600) 0 :: IO (VUM.IOVector Int)
  rep 600 $ \i -> rep' i $ \j -> if j == 0 || j == i
    then VUM.unsafeWrite c (i * 600 + j) 1
    else do
      item1 <- VUM.unsafeRead c ((i - 1) * 600 + j)
      item2 <- VUM.unsafeRead c ((i - 1) * 600 + j - 1)
      VUM.unsafeWrite c (i * 600 + j) ((item1 + item2) `mod` modulus)
  rep1 600 $ \i -> do
    VUM.unsafeWrite a (i * 600 + 1) 1
    range 2 i $ \j -> do
      item1 <- VUM.unsafeRead a ((i - 1) * 600 + j)
      item2 <- VUM.unsafeRead a ((i - 1) * 600 + j - 1)
      VUM.unsafeWrite a ((i - 1) * 600 + j) ((item1 * j + item2) `mod` modulus)
  rep1 600 $ \i -> do
    VUM.unsafeWrite b (i * 600) 1
    rep1 600 $ \j -> do
      item <- VUM.unsafeRead b (i * 600 + j - 1)
      VUM.unsafeWrite b (i * 600 + j) (item * i * (i - 1) `mod` modulus)
  ansRef <- newIORef (0 :: Int)
  rep1' n $ \x -> rep1' x $ \y -> do
    let z = n - x
    temp <- VUM.unsafeRead c (n * 600 + x)
    axy <- VUM.unsafeRead a (x * 600 + y)
    byz <- VUM.unsafeRead b (y * 600 + z)
    let
      temp' = temp * axy `mod` modulus
      temp'' = temp' * byz `mod` modulus
    modifyIORef' ansRef (flip mod modulus . (+ temp''))
  print =<< readIORef ansRef

-------------------------------------------------------------------------------
-- for
-------------------------------------------------------------------------------
rep :: Monad m => Int -> (Int -> m ()) -> m ()
rep n = flip VFSM.mapM_ (stream 0 n)
{-# INLINE rep #-}

rep' :: Monad m => Int -> (Int -> m ()) -> m ()
rep' n = flip VFSM.mapM_ (stream 0 (n + 1))
{-# INLINE rep' #-}

rep1 :: Monad m => Int -> (Int -> m ()) -> m ()
rep1 n = flip VFSM.mapM_ (stream 1 n)
{-# INLINE rep1 #-}

rep1' :: Monad m => Int -> (Int -> m ()) -> m ()
rep1' n = flip VFSM.mapM_ (stream 1 (n + 1))
{-# INLINE rep1' #-}

rev :: Monad m => Int -> (Int -> m ()) -> m ()
rev n = flip VFSM.mapM_ (streamR 0 n)
{-# INLINE rev #-}

rev' :: Monad m => Int -> (Int -> m ()) -> m ()
rev' n = flip VFSM.mapM_ (streamR 0 (n + 1))
{-# INLINE rev' #-}

rev1 :: Monad m => Int -> (Int -> m ()) -> m ()
rev1 n = flip VFSM.mapM_ (streamR 1 n)
{-# INLINE rev1 #-}

rev1' :: Monad m => Int -> (Int -> m ()) -> m ()
rev1' n = flip VFSM.mapM_ (streamR 1 (n + 1))
{-# INLINE rev1' #-}

range :: Monad m => Int -> Int -> (Int -> m ()) -> m ()
range l r = flip VFSM.mapM_ (stream l (r + 1))
{-# INLINE range #-}

rangeR :: Monad m => Int -> Int -> (Int -> m ()) -> m ()
rangeR r l = flip VFSM.mapM_ (streamR l (r + 1))
{-# INLINE rangeR #-}

forStep :: Monad m => Int -> Int -> Int -> (Int -> m ()) -> m ()
forStep l r d = flip VFSM.mapM_ (streamStep l r d)
{-# INLINE forStep #-}

forStepR :: Monad m => Int -> Int -> Int -> (Int -> m ()) -> m ()
forStepR r l d = flip VFSM.mapM_ (streamStepR l r d)
{-# INLINE forStepR #-}

forP :: Monad m => Int -> (Int -> m ()) -> m ()
forP p = flip VFSM.mapM_ (streamG 2 p (^) 2 (+) 1)
{-# INLINE forP #-}

forG :: Monad m => Int -> Int -> (Int -> Int -> Int) -> Int -> (Int -> Int -> Int) -> Int -> (Int -> m ()) -> m ()
forG l r f p g d = flip VFSM.mapM_ (streamG l r f p g d)
{-# INLINE forG #-}

forRG :: Monad m => Int -> Int -> (Int -> Int -> Int) -> Int -> (Int -> Int -> Int) -> Int -> (Int -> m ()) -> m ()
forRG r l f p g d = flip VFSM.mapM_ (streamRG r l f p g d)
{-# INLINE forRG #-}

stream :: Monad m => Int -> Int -> VFSM.Stream m Int
stream !l !r = VFSM.Stream step l
  where
    step x
      | x < r     = return $ VFSM.Yield x (x + 1)
      | otherwise = return VFSM.Done
    {-# INLINE [0] step #-}
{-# INLINE [1] stream #-}

streamR :: Monad m => Int -> Int -> VFSM.Stream m Int
streamR !l !r = VFSM.Stream step (r - 1)
  where
    step x
      | x >= l = return $ VFSM.Yield x (x - 1)
      | otherwise = return VFSM.Done
    {-# INLINE [0] step #-}
{-# INLINE [1] streamR #-}

streamStep :: Monad m => Int -> Int -> Int -> VFSM.Stream m Int
streamStep !l !r !d = VFSM.Stream step l
  where
    step x
      | x <= r    = return $ VFSM.Yield x (x + d)
      | otherwise = return VFSM.Done
    {-# INLINE [0] step #-}
{-# INLINE [1] streamStep #-}

streamStepR :: Monad m => Int -> Int -> Int -> VFSM.Stream m Int
streamStepR !l !r !d = VFSM.Stream step r
  where
    step x
      | x >= l    = return $ VFSM.Yield x (x - d)
      | otherwise = return VFSM.Done
    {-# INLINE [0] step #-}
{-# INLINE [1] streamStepR #-}

streamG :: Monad m => Int -> Int -> (Int -> Int -> Int) -> Int -> (Int -> Int -> Int) -> Int -> VFSM.Stream m Int
streamG !l !r !f !p !g !d = VFSM.Stream step l
  where
    step x
      | f x p <= r = return $ VFSM.Yield x (g x d)
      | otherwise  = return VFSM.Done
    {-# INLINE [0] step #-}
{-# INLINE [1] streamG #-}

streamRG :: Monad m => Int -> Int -> (Int -> Int -> Int) -> Int -> (Int -> Int -> Int) -> Int -> VFSM.Stream m Int
streamRG !r !l !f !p !g !d = VFSM.Stream step r
  where
    step x
      | f x p >= l = return $ VFSM.Yield x (g x d)
      | otherwise  = return VFSM.Done
    {-# INLINE [0] step #-}
{-# INLINE [1] streamRG #-}

withBreakIO :: ((r -> ContT r IO b) -> ContT r IO r) -> IO r
withBreakIO = flip runContT pure . callCC
{-# INLINE withBreakIO #-}

withBreakST :: ((r -> ContT r (ST s) b) -> ContT r (ST s) r) -> (ST s) r
withBreakST = flip runContT pure . callCC
{-# INLINE withBreakST #-}