it seems this is a 2 month old thread that I've just noticed now, but what the heck. I've designed and developed the gameplay framework for a commercial, networked board game before. We had a very pleasant experience working with it.
Your game can probably be in a (close to) infinite amount of states because of the permutations of things like how much money player A has, how much money player B has, and etc... Therefore, I'm pretty sure you want to stay away from state machines.
The idea behind our framework was to represent the game state as structure with all the data fields that together, provide the complete game state (ie: if you wanted to save the game to disk, you write that structure out).
We used the Command Pattern to represent all of the valid game actions a player could make. Here would be an example action:
class RollDice : public Action
virtual void Apply(GameState& gameState) const; // Apply the action to the gamestate, modifying the gamestate
virtual bool IsLegal(const GameState& gameState) const; // Returns true if this is a legal action
So you see that to decide whether a move is valid, you can construct that action and then call its IsLegal function, passing in the current game state. If it is valid, and the player confirms the action, you can call the Apply function to actually modify the game state. By ensuring that your gameplay code can only modify the game state by creating and submitting legal Actions (so in other words, the Action::Apply family of methods are the only thing that directly modifies the game state), then you ensure that your game state will never be invalid. Furthermore, by using the command pattern, you make it possible to serialize your player's desired moves and send them over a network to be executed on other player's game states.
There ended up being one gotcha with this system that turned out to have a fairly elegant solution. Sometimes actions would have two or more phases. For example, the player may land on a property in Monopoly and must now make a new decision. What is the game state between when the player rolled the dice, and before they decide to purchase a property or not? We managed situations like this by featuring an "Action Context" member of our game state. The action context would normally be null, indicating that the game is not currently in any special state. When the player rolls the dice and the dice rolling action is applied to the game state, it will realize that the player has landed on an un-owned property, and can create a new "PlayerDecideToPurchaseProperty" action context that contains the index of the player we are waiting for a decision from. By the time the RollDice action has completed, our game state represents that it is currently waiting for the specified player to decide whether to buy a property is not. It is now easy for all other actions' IsLegal method to return false, except for the "BuyProperty" and "PassPropertyPurchaseOpportunity" actions, which are only legal when the game state has the "PlayerDecideToPurchaseProperty" action context.
Through the use of action contexts, there is never a single point in the life-time of the board game where the game state structure does not completely represent EXACTLY what is happening in the game at that point in time. This is a very desirable property of your board game system. It will it much easier for you to write code when you can find everything you ever want to know about what's happening in the game by examining only one structure.
Furthermore, it extends very nicely to networked environments, where clients can submit their actions over a network to a host machine, which can apply the action to the host's "official" game state, and then echo that action back to all the other clients to have them apply it to their replicated game states.
I hope this was concise and helpful.