It is not lazy because the `Get`

monad is a strict state monad (in binary-0.5.0.2 to 0.5.1.1; it was a lazy state monad before, and in binary-0.6.* it has become a continuation monad, I haven't analysed the strictness implications of that change):

```
-- | The parse state
data S = S {-# UNPACK #-} !B.ByteString -- current chunk
L.ByteString -- the rest of the input
{-# UNPACK #-} !Int64 -- bytes read
-- | The Get monad is just a State monad carrying around the input ByteString
-- We treat it as a strict state monad.
newtype Get a = Get { unGet :: S -> (# a, S #) }
-- Definition directly from Control.Monad.State.Strict
instance Monad Get where
return a = Get $ \s -> (# a, s #)
{-# INLINE return #-}
m >>= k = Get $ \s -> case unGet m s of
(# a, s' #) -> unGet (k a) s'
{-# INLINE (>>=) #-}
```

thus the final recursive

```
get >>= \x ->
get >>= \(Stream xs) ->
return (Stream (x:xs))
```

forces the entire `Stream`

to be read before it can be returned.

I don't think it's possible to lazily decode a `Stream`

in the `Get`

monad (so a fortiori not with the `Binary`

instance). But you can write a lazy decoding function using `runGetState`

:

```
-- | Run the Get monad applies a 'get'-based parser on the input
-- ByteString. Additional to the result of get it returns the number of
-- consumed bytes and the rest of the input.
runGetState :: Get a -> L.ByteString -> Int64 -> (a, L.ByteString, Int64)
runGetState m str off =
case unGet m (mkState str off) of
(# a, ~(S s ss newOff) #) -> (a, s `join` ss, newOff)
```

First write a `Get`

parser that returns a `Maybe a`

,

```
getMaybe :: Binary a => Get (Maybe a)
getMaybe = do
t <- getWord8
case t of
0 -> return Nothing
_ -> fmap Just get
```

then use that to make a function of type `(ByteString,Int64) -> Maybe (a,(ByteString,Int64))`

:

```
step :: Binary a => (ByteString,Int64) -> Maybe (a,(ByteString,Int64))
step (xs,offset) = case runGetState getMaybe xs offset of
(Just v, ys, newOffset) -> Just (v,(ys,newOffset))
_ -> Nothing
```

and then you can use `Data.List.unfoldr`

to lazily decode a list,

```
lazyDecodeList :: Binary a => ByteString -> [a]
lazyDecodeList xs = unfoldr step (xs,0)
```

and wrap that in a `Stream`

```
lazyDecodeStream :: Binary a => ByteString -> Stream a
lazyDecodeStream = Stream . lazyDecodeList
```