A monad essentially is used to allow access at global value and in the same time to hide the global value from the parameter list of the function.

The idea is, the a function call, in order to simulate a global, receives its actual arguments and also the global and returns the value and the new global. The monad is used to do this in an elegant way by hiding the global value.

For a monad of type `Mx`

, each monadic operation is a closure that encloses a value of type `x`

. The monadic operation says `"pass me the global value and I provide you the result consisting of the new value of the global and in the same time the value you need to compute"`

-- this statement is the same for any monad, including the continuation monad.

There are 2 operators that are enough to make any computation as a monad and both of them follow the logic of this statement.

The `return`

operator simply packs the value to be computed in the environment of a closure that does no computation. This closure waits for the global value and provides the answer

The `bind`

operator also is waiting for a global value but it makes some computation before to provide the answer. It unpacks the value enclosed in the monad (it unpacks the value enclosed by the closure representing the monad), makes some computation in 2 continuations that are passed once the global value and other one that is passed the value computed by the first continuation and returns a new closure enclosing the computed value as a monadic value.

Now , to answer your question, from the viewpoint just described, *the unit-law composition* says that the `return`

operator is never allowed to change the value of the global variable that it receives, otherwise, even if the code is semantically correct, it is no more a monad pattern due to type checking.

The `associative law`

means that the order of monadic compositions is not important. This is in agreement with the lazy evaluation and mathematical model of composing the same operator in associative way.