Fluent API for creating hierarchical finite state machines in C#.
- A basic example - creating a state machine with a single state
- Conditions
- Using multiple states
- Nesting states
- Pushing and popping nested states
- Events
- Custom states
- Examples
Reference the dll and include the namespace:
using RSG;
Create a state via the builder class:
var rootState = new StateMachineBuilder()
.State("main")
.Enter(state => {
Console.WriteLine("Entered main state");
})
.Update((state, deltaTime) => {
Console.WriteLine("Updating main state");
})
.End()
.Build();
Calling Build() on our StateMachineBuilder sets up all the states we've specified and returns a root
state which is automatically created to be the parent of any top-level states we create.
The function in Enter will be called once when we first enter the state, and the function in Update
will be called every time we update the state.
Once our state machine is set up, we then need to set the initial state:
rootState.ChangeState("main");
Finally, we can update our currently active state with a specified time since the last update as follows:
rootState.Update(timeSinceLastFrame);
As well as Enter and Update, conditions can be set up, which are functions called when the state is updated only when a specified predicate is satisfied.
var rootState = new StateMachineBuilder()
.State("main")
.Enter(state => {
Console.WriteLine("Entered main state");
})
.Update((state, deltaTime) => {
Console.WriteLine("Updating main state");
})
.Condition(() => SomeBoolean, state => {
Console.WriteLine("Condition satisfied");
})
.End()
.Build();
The predicate to the condition is also a function, and this function will be invoked every time the state is updated.
Switch between states by using IState.ChangeState(stateName)
var rootState = new StateMachineBuilder()
.State("main")
.Enter(state => {
Console.WriteLine("Entered main state");
})
.Update((state, deltaTime) => {
Console.WriteLine("Updating main state");
})
.Condition(() => SomeBoolean, state => {
state.Parent.ChangeState("secondary");
})
.Exit(state => {
Console.WriteLine("Exited main state");
})
.End()
.State("secondary")
.Enter(state => {
Console.WriteLine("Entered secondary state")
})
.End()
.Build();
ChangeState will attempt to exit the current state and change to the specified one. Note that since
both our "main" state and "secondary" states are children of the root state, we actually need to call
ChangeState on the main state's parent (which in this case is the root state).
The function specified in Exit will be called when we exit the main state.
Nested states, sometimes referred to as super-states are useful for encapsulating different parts of logic and simplifying transitions between states.
var rootState = new StateMachineBuilder()
.State("main")
.Enter(state => {
Console.WriteLine("Entered main state");
})
.Update((state, deltaTime) => {
Console.WriteLine("Updating main state");
})
.Condition(() => SomeBoolean, state => {
state.ChangeState("child");
})
.Exit(state => {
Console.WriteLine("Exited main state");
})
.State("child")
.Enter(state => {
Console.WriteLine("Entered secondary state")
})
.End()
.End()
.Build();
Our second state is now a child of the main state. This example doesn't really add any extra
functionality but serves to show how a nesting can work in its most basic form. Note that Exit is
not called on the main state when we change to it even though it is no longer being updated, since
it is still technically active but only the end of the tree is updated.
In addition to a list of children, each state contains a stack of active children
var rootState = new StateMachineBuilder()
.State("main")
.Enter(state => {
Console.WriteLine("Entered main state");
})
.Update((state, deltaTime) => {
Console.WriteLine("Updating main state");
})
.Condition(() => SomeBoolean, state => {
state.PushState("firstChild");
})
.Exit(state => {
Console.WriteLine("Exited main state");
})
.State("firstChild")
.Enter(state => {
Console.WriteLine("Entered secondary state")
})
.Condition(() => SomeBoolean, state => {
state.Parent.PushState("secondChild");
})
.End()
.State("secondChild")
.Enter(state => {
Console.WriteLine("Entered third child state")
})
.Condition(() => ShouldPopState, state => {
state.Parent.PopState();
})
.End()
.End()
.Build();
In this example, we will start out in main, then when SomeBoolean is true we'll go to firstChild.
If SomeBoolean is still true we will transition to secondChild, and then when ShouldPopState is
true we will go back the previous state on the stack (in this case firstChild).
The state builder doesn't give us a reference to the new states it creates, but if we want to trigger an action on the currently active state that we don't want to run every frame (like a condition) we can use an event.
var rootState = new StateMachineBuilder()
.State("main")
.Enter(state => {
Console.WriteLine("Entered main state");
})
.Update((state, deltaTime) => {
Console.WriteLine("Updating main state");
})
.Condition(() => SomeBoolean, state => {
state.ChangeState("child");
})
.State("child")
.Enter(state => {
Console.WriteLine("Entered secondary state")
})
.Event("MyEvent", state => {
Console.WriteLine("MyEvent triggered");
});
.End()
.End()
.Build();
Invoking the event on the root state will trigger it on whatever the currently active state is:
rootState.TriggerEvent("MyEvent");
Sometimes we will want to have data shared by the Enter, Update, Condition, Event and Exit functions
of a state, specific to that state, or we might want to have some methods that are internal to just
that state. This an be achieved by creating a sub-class of AbstractState that has our extra
functionality in it, and specifying this when we create the state.
class MainState : AbstractState
{
public string updateMessage = "Updating main state";
public void PushChildState()
{
PushState("child");
}
}
Note that since this class inherits from AbstractState, it has full access to methods for pushing, popping and changing states. Since this will be newed-up by the state builder it must have either no constructor or a parameterless constructor.
Setting up the state is basically the same as it would otherwise be except that we now also specify the type of the state. The name field is now optional since the builder can just automatically take the name from the name of the class it uses, although since no two states that are children of the same state can have the same name, this can only be done once per type of state for each group.
var rootState = new StateMachineBuilder()
.State<MainState>()
.Enter(state => {
Console.WriteLine("Entered main state");
})
.Update((state, deltaTime) => {
Console.WriteLine(state.updateMessage);
})
.Condition(() => SomeBoolean, state => {
state.PushChildState();
})
.State("child")
.Enter(state => {
Console.WriteLine("Entered secondary state")
})
.Event("MyEvent", state => {
Console.WriteLine("MyEvent triggered");
});
.End()
.End()
.Build();
In the Examples directory there are a couple of example projects to demonstrate usage of the library.
This sample demonstrates a fairly simple state machine with custom nested states, from a console app.
This sample comes as a Unity project and shows how one could set up the library for use in a Unity game, as well as using events to trigger actions in response to Unity physics collision events.
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