# Simple state machine example in C#?

Update:

Again thanks for the examples, they have been very helpful and with the following I don't mean to take anything away from them.

Aren't the currently given examples, as far as I understand them & state-machines, only half of what we usually understand by a state-machine?
In the sense that the examples do change state but that's only represented by changing the value of a variable (and allowing different value- changes in different states), while usually a state machine should also change it's behavior, and behavior not (only) in the sense of allowing different value changes for a variable depending on state, but in the sense of allowing different methods to be executed for different states.

Or do I have a misconception of state machines and their common use?

Best regards

Original question:

I found this discussion about state machines & iterator blocks in c# and tools to create state machines and what not for C#, so I found a lot of abstract stuff but as a noob all of this is a little confusing.

So it would be great if someone could provide a C# source code-example that realizes a simple state machine with perhaps 3,4 states, just to get the gist of it.

• Are you wondering about state machines in general or just iterator based ones? – Skurmedel May 7 '11 at 21:15
• There is .Net Core Stateless lib with examples, DAGs daigram etc. - worth reviewing: hanselman.com/blog/… – zmische Mar 21 '17 at 8:22

We have:

• 4 states (Inactive, Active, Paused, and Exited)
• 5 types of state transitions (Begin Command, End Command, Pause Command, Resume Command, Exit Command).

You can convert this to C# in a handful of ways, such as performing a switch statement on the current state and command, or looking up transitions in a transition table. For this simple state machine, I prefer a transition table, which is very easy to represent using a Dictionary:

using System;
using System.Collections.Generic;

namespace Juliet
{
public enum ProcessState
{
Inactive,
Active,
Paused,
Terminated
}

public enum Command
{
Begin,
End,
Pause,
Resume,
Exit
}

public class Process
{
class StateTransition
{

public StateTransition(ProcessState currentState, Command command)
{
CurrentState = currentState;
Command = command;
}

public override int GetHashCode()
{
return 17 + 31 * CurrentState.GetHashCode() + 31 * Command.GetHashCode();
}

public override bool Equals(object obj)
{
StateTransition other = obj as StateTransition;
return other != null && this.CurrentState == other.CurrentState && this.Command == other.Command;
}
}

Dictionary<StateTransition, ProcessState> transitions;
public ProcessState CurrentState { get; private set; }

public Process()
{
CurrentState = ProcessState.Inactive;
transitions = new Dictionary<StateTransition, ProcessState>
{
{ new StateTransition(ProcessState.Inactive, Command.Exit), ProcessState.Terminated },
{ new StateTransition(ProcessState.Inactive, Command.Begin), ProcessState.Active },
{ new StateTransition(ProcessState.Active, Command.End), ProcessState.Inactive },
{ new StateTransition(ProcessState.Active, Command.Pause), ProcessState.Paused },
{ new StateTransition(ProcessState.Paused, Command.End), ProcessState.Inactive },
{ new StateTransition(ProcessState.Paused, Command.Resume), ProcessState.Active }
};
}

public ProcessState GetNext(Command command)
{
StateTransition transition = new StateTransition(CurrentState, command);
ProcessState nextState;
if (!transitions.TryGetValue(transition, out nextState))
throw new Exception("Invalid transition: " + CurrentState + " -> " + command);
return nextState;
}

public ProcessState MoveNext(Command command)
{
CurrentState = GetNext(command);
return CurrentState;
}
}

public class Program
{
static void Main(string[] args)
{
Process p = new Process();
Console.WriteLine("Current State = " + p.CurrentState);
Console.WriteLine("Command.Begin: Current State = " + p.MoveNext(Command.Begin));
Console.WriteLine("Command.Pause: Current State = " + p.MoveNext(Command.Pause));
Console.WriteLine("Command.End: Current State = " + p.MoveNext(Command.End));
Console.WriteLine("Command.Exit: Current State = " + p.MoveNext(Command.Exit));
}
}
}


As a matter of personal preference, I like to design my state machines with a GetNext function to return the next state deterministically, and a MoveNext function to mutate the state machine.

• +1 for the correct implementation of GetHashCode() using primes. – ja72 May 8 '11 at 0:05
• Could you please explain me the purpose of GetHashCode()? – Siddharth Sep 5 '12 at 13:46
• @Siddharth: The StateTransition class is used as key in the dictionary and equality of keys are important. Two distinct instances of StateTransition should be considered equal as long as they represent the same transition (e.g. CurrentState and Command are the same). To implement equality you have to override Equals as well as GetHashCode. In particular the dictionary will use the hash code and two equal objects must return the same hash code. You also get good performance if not too many non-equal objects share the same hash code which is why GetHashCode is implemented as shown. – Martin Liversage Nov 9 '12 at 10:25
• While this surely gets you a state machine (and a proper C#'ish implementation as well), I feel it is still missing the answer to the OP's question about changing behaviour? After all, it just calculates states but the behaviour related to state changes, the actual meat of the program and usually called Entry/Exit events, is still missing. – stijn Jan 11 '15 at 8:45
• If someone it's gonna need it: I adjusted this tate machine and used it in my unity game. It's available on git hub: github.com/MarcoMig/Finite-State-Machine-FSM – Max_Power89 Mar 16 '15 at 15:15

You might want to use one of the existing open source Finite State Machines. E.g. bbv.Common.StateMachine found at http://code.google.com/p/bbvcommon/wiki/StateMachine. It has a very intuitive fluent syntax and a lot of features such as, enter/exit actions, transition actions, guards, hierarchical, passive implementation (executed on the thread of the caller) and active implementation (own thread on which the fsm runs, events are added to a queue).

Taking Juliets example the definition for the state machine gets very easy:

var fsm = new PassiveStateMachine<ProcessState, Command>();
fsm.In(ProcessState.Inactive)
.On(Command.Exit).Goto(ProcessState.Terminated).Execute(SomeTransitionAction)
.On(Command.Begin).Goto(ProcessState.Active);
fsm.In(ProcessState.Active)
.ExecuteOnEntry(SomeEntryAction)
.ExecuteOnExit(SomeExitAction)
.On(Command.End).Goto(ProcessState.Inactive)
.On(Command.Pause).Goto(ProcessState.Paused);
fsm.In(ProcessState.Paused)
.On(Command.End).Goto(ProcessState.Inactive).OnlyIf(SomeGuard)
.On(Command.Resume).Goto(ProcessState.Active);
fsm.Initialize(ProcessState.Inactive);
fsm.Start();

fsm.Fire(Command.Begin);


Update: The project location has moved to: https://github.com/appccelerate/statemachine

• Thank you for referencing this excellent open source state machine. Can I ask how can I get current state ? – Ramazan Polat Nov 10 '12 at 2:48
• You can't and you shouldn't. State is something unstable. When you request the state it is possible that you are in the middle of a transition. All actions should be done within transitions, state entry and state exits. If you really want to have the state then you can add a local field and assign the state in a entry action. – Remo Gloor Nov 11 '12 at 4:53
• The question is for what do you "need" it and if you really need the SM state or some other kind of state. E.g. if you need some display text then several stated could have the same display text for example if preparing for send has multiple sub states. In this case you should do exactly what you intend to do. Update some display text at the correct places. E.g. within ExecuteOnEntry. If you need more info then ask a new Question and state exactly your problem as this is getting off topic here. – Remo Gloor Nov 12 '12 at 12:30
• Ok I am asking a new question and waiting you to reply. Because I don't think somebody else solve this problem since you have the best answer but still questioner didn't accept. I will post question url here. Thanks. – Ramazan Polat Nov 12 '12 at 20:01
• +1 for the fluent and declarative API. It's awesome. BTW, the google code seems to be outdated. Their newest project site is on GitHub here – KFL Jul 4 '14 at 22:57

Here's an example of a very classic finite state machine, modelling a very simplified electronic device (like a TV)

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace fsm
{
class Program
{
static void Main(string[] args)
{
var fsm = new FiniteStateMachine();
Console.WriteLine(fsm.State);
fsm.ProcessEvent(FiniteStateMachine.Events.PlugIn);
Console.WriteLine(fsm.State);
fsm.ProcessEvent(FiniteStateMachine.Events.TurnOn);
Console.WriteLine(fsm.State);
fsm.ProcessEvent(FiniteStateMachine.Events.TurnOff);
Console.WriteLine(fsm.State);
fsm.ProcessEvent(FiniteStateMachine.Events.TurnOn);
Console.WriteLine(fsm.State);
fsm.ProcessEvent(FiniteStateMachine.Events.RemovePower);
Console.WriteLine(fsm.State);
}

class FiniteStateMachine
{
public enum States { Start, Standby, On };
public States State { get; set; }

public enum Events { PlugIn, TurnOn, TurnOff, RemovePower };

private Action[,] fsm;

public FiniteStateMachine()
{
this.fsm = new Action[3, 4] {
//PlugIn,       TurnOn,                 TurnOff,            RemovePower
{this.PowerOn,  null,                   null,               null},              //start
{null,          this.StandbyWhenOff,    null,               this.PowerOff},     //standby
{null,          null,                   this.StandbyWhenOn, this.PowerOff} };   //on
}
public void ProcessEvent(Events theEvent)
{
this.fsm[(int)this.State, (int)theEvent].Invoke();
}

private void PowerOn() { this.State = States.Standby; }
private void PowerOff() { this.State = States.Start; }
private void StandbyWhenOn() { this.State = States.Standby; }
private void StandbyWhenOff() { this.State = States.On; }
}
}
}

• for anyone new to state machines, this is an excellent first example to get ones feet wet first. – PositiveGuy Jan 9 '13 at 4:50
• I am new to state machines and seriously, this has brought me The Light - thanks! – MC5 Dec 2 '13 at 17:35
• I liked this implementation. For anyone who might stumble on this, a slight "improvement". In the FSM class, I added private void DoNothing() {return;} and replaced all instances of null with this.DoNothing. Has the pleasant side effect of returning the current state. – Sethmo011 Oct 31 '15 at 19:05

Some shameless self-promo here, but a while ago I created a library called YieldMachine which allows a limited-complexity state machine to be described in a very clean and simple way. For example, consider a lamp:

Notice that this state machine has 2 triggers and 3 states. In YieldMachine code, we write a single method for all state-related behavior, in which we commit the horrible atrocity of using goto for each state. A trigger becomes a property or field of type Action, decorated with an attribute called Trigger. I've commented the code of the first state and its transitions below; the next states follow the same pattern.

public class Lamp : StateMachine
{
// Triggers (or events, or actions, whatever) that our
// state machine understands.
[Trigger]

[Trigger]

// Actual state machine logic
protected override IEnumerable WalkStates()
{
off:
Console.WriteLine("off.");
yield return null;

if (Trigger == PressSwitch) goto on;
InvalidTrigger();

on:
Console.WriteLine("*shiiine!*");
yield return null;

if (Trigger == GotError) goto error;
if (Trigger == PressSwitch) goto off;
InvalidTrigger();

error:
Console.WriteLine("-err-");
yield return null;

if (Trigger == PressSwitch) goto off;
InvalidTrigger();
}
}


Short and nice, eh!

This state machine is controlled simply by sending triggers to it:

var sm = new Lamp();
sm.PressSwitch(); //go on
sm.PressSwitch(); //go off

sm.PressSwitch(); //go on
sm.GotError();    //get error
sm.PressSwitch(); //go off


    protected override IEnumerable WalkStates()
{
off:                                       // Each goto label is a state

Console.WriteLine("off.");             // State entry actions

yield return null;                     // This means "Wait until a
// trigger is called"

// Ah, we got triggered!
//   perform state exit actions
//   (none, in this case)

if (Trigger == PressSwitch) goto on;   // Transitions go here:
// depending on the trigger
// that was called, go to
// the right state

InvalidTrigger();                      // Throw exception on
// invalid trigger

...


This works because the C# compiler actually created a state machine internally for each method that uses yield return. This construct is usually used to lazily create sequences of data, but in this case we're not actually interested in the returned sequence (which is all nulls anyway), but in the state behaviour that gets created under the hood.

The StateMachine base class does some reflection on construction to assign code to each [Trigger] action, which sets the Trigger member and moves the state machine forward.

But you don't really need to understand the internals to be able to use it.

• The "goto" is only atrocious if it jumps between methods. That, fortunately, is not allowed in C#. – Brannon May 1 '13 at 17:55
• Good point! In fact, I would be very impressed if any statically typed language would manage to allow a goto between methods. – skrebbel May 3 '13 at 11:01
• @Brannon: which language allows goto to jump between methods? I don't see how that would possibly work. No, goto is problematic because it results in procedural programming (this by itself complicates nice things like unit testing), promotes code repetition (noticed how InvalidTrigger needs to be inserted for every state?) and finally makes the program flow harder to follow. Compare this to (most) other solutions in this thread and you will see that this is the only one where the entire FSM happens in a single method. That's usually enough to raise a concern. – Groo May 11 '14 at 22:20
• @Groo, GW-BASIC, for instance. It helps that it doesn't have methods, or even functions. Besides that, I have a very hard time understanding why you find the "program flow harder to follow" in this example. It's a state machine, "going to" a state from another one is the only thing you do. This maps to goto pretty well. – skrebbel May 12 '14 at 11:23
• GW-BASIC allows goto to jump between functions, but it doesn't support functions? :) You're right, the "harder to follow" remark is more a general goto issue , indeed not that much of a problem in this case. – Groo May 12 '14 at 11:43

You can code an iterator block that lets you execute a code block in an orchestrated fashion. How the code block is broken up really doesn't have to correspond to anything, it's just how you want to code it. For example:

IEnumerable<int> CountToTen()
{
System.Console.WriteLine("1");
yield return 0;
System.Console.WriteLine("2");
System.Console.WriteLine("3");
System.Console.WriteLine("4");
yield return 0;
System.Console.WriteLine("5");
System.Console.WriteLine("6");
System.Console.WriteLine("7");
yield return 0;
System.Console.WriteLine("8");
yield return 0;
System.Console.WriteLine("9");
System.Console.WriteLine("10");
}


In this case, when you call CountToTen, nothing actually executes, yet. What you get is effectively a state machine generator, for which you can create a new instance of the state machine. You do this by calling GetEnumerator(). The resulting IEnumerator is effectively a state machine that you can drive by calling MoveNext(...).

Thus, in this example, the first time you call MoveNext(...) you will see "1" written to the console, and the next time you call MoveNext(...) you will see 2, 3, 4, and then 5, 6, 7 and then 8, and then 9, 10. As you can see, it's a useful mechanism for orchestrating how things should occur.

• Obligatory link to fair warning – sehe May 7 '11 at 20:52
• Definitely a good link, thanks! – Kevin Hsu May 7 '11 at 21:02

Im posting annother answer here as this is state machines from a different perspective; very visual.

My origianl answer is clasic imperitive code. I think its quite visual as code goes becuase of the array which makes visualising the state machine simple. The downside is you have to write all this. Remos's answer aleviates the effort of writing the boiler-plate code but is far less visual. There is the third alternative; really drawing the state machine.

If you are using .NET and can target version 4 of the run time then you have the option of using workflow's state machine activities. These in essence let you draw the state machine (much as in Juliet's diagram) and have the WF runtime execute it for you.

See the MSDN article Building State Machines with Windows Workflow Foundation for more details, and this CodePlex site for the latest version.

Thats the option I would always prefer when targeting .NET because its easy to see, change and explain to non programmers; pictures are worth a thousand words as they say!

• I think the state machine is one of the best parts of the whole workflow foundation! – fabsenet Jul 9 '15 at 12:31

It's useful to remember that state machines are an abstraction, and you don't need particular tools to create one, however tools can be useful.

You can for example realise a state machine with functions:

void Hunt(IList<Gull> gulls)
{
if (gulls.Empty())
return;

var target = gulls.First();
TargetAcquired(target, gulls);
}

void TargetAcquired(Gull target, IList<Gull> gulls)
{
var balloon = new WaterBalloon(weightKg: 20);

this.Cannon.Fire(balloon);

if (balloon.Hit)
{
TargetHit(target, gulls);
}
else
TargetMissed(target, gulls);
}

void TargetHit(Gull target, IList<Gull> gulls)
{
Console.WriteLine("Suck on it {0}!", target.Name);
Hunt(gulls);
}

void TargetMissed(Gull target, IList<Gull> gulls)
{
Console.WriteLine("I'll get ya!");
TargetAcquired(target, gulls);
}


This machine would hunt for gulls and try to hit them with water balloons. If it misses it will try firing one until it hits (could do with some realistic expectations ;)), otherwise it will gloat in the console. It continues to hunt until it's out of gulls to harass.

Each function corresponds to each state; the start and end (or accept) states are not shown. There are probably more states in there than modelled by the functions though. For example after firing the balloon the machine is really in another state than it was before it, but I decided this distinction was impractical to make.

A common way is to use classes to represent states, and then connect them in different ways.

Found this great tutorial online and it helped me wrap my head around finite state machines.

http://gamedevelopment.tutsplus.com/tutorials/finite-state-machines-theory-and-implementation--gamedev-11867

The tutorial is language agnostic, so it can easily be adapted to your C# needs.

Also, the example used (an ant looking for food) is easy to understand.

From the tutorial:

public class FSM {
private var activeState :Function; // points to the currently active state function

public function FSM() {
}

public function setState(state :Function) :void {
activeState = state;
}

public function update() :void {
if (activeState != null) {
activeState();
}
}
}

public class Ant
{
public var position   :Vector3D;
public var velocity   :Vector3D;
public var brain      :FSM;

public function Ant(posX :Number, posY :Number) {
position    = new Vector3D(posX, posY);
velocity    = new Vector3D( -1, -1);
brain       = new FSM();

// Tell the brain to start looking for the leaf.
brain.setState(findLeaf);
}

/**
* The "findLeaf" state.
* It makes the ant move towards the leaf.
*/
public function findLeaf() :void {
// Move the ant towards the leaf.
velocity = new Vector3D(Game.instance.leaf.x - position.x, Game.instance.leaf.y - position.y);

if (distance(Game.instance.leaf, this) <= 10) {
// The ant is extremelly close to the leaf, it's time
// to go home.
brain.setState(goHome);
}

if (distance(Game.mouse, this) <= MOUSE_THREAT_RADIUS) {
// Mouse cursor is threatening us. Let's run away!
// It will make the brain start calling runAway() from
// now on.
brain.setState(runAway);
}
}

/**
* The "goHome" state.
* It makes the ant move towards its home.
*/
public function goHome() :void {
// Move the ant towards home
velocity = new Vector3D(Game.instance.home.x - position.x, Game.instance.home.y - position.y);

if (distance(Game.instance.home, this) <= 10) {
// The ant is home, let's find the leaf again.
brain.setState(findLeaf);
}
}

/**
* The "runAway" state.
* It makes the ant run away from the mouse cursor.
*/
public function runAway() :void {
// Move the ant away from the mouse cursor
velocity = new Vector3D(position.x - Game.mouse.x, position.y - Game.mouse.y);

// Is the mouse cursor still close?
if (distance(Game.mouse, this) > MOUSE_THREAT_RADIUS) {
// No, the mouse cursor has gone away. Let's go back looking for the leaf.
brain.setState(findLeaf);
}
}

public function update():void {
// Update the FSM controlling the "brain". It will invoke the currently
// active state function: findLeaf(), goHome() or runAway().
brain.update();

// Apply the velocity vector to the position, making the ant move.
moveBasedOnVelocity();
}

(...)
}

• While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. - From Review – drneel Apr 21 '16 at 13:25
• @drneel I could copy and paste bits from the tutorial... but would that not be taking credit away from the author? – Jet Blue Apr 21 '16 at 18:08
• @JetBlue: Leave the link in the answer as a reference, and include the relevant bits in your own words in the answer post so as not to break anyone's copyright. I know it seems strict but but many answers have become much, much better because of this rule. – Flimm Apr 21 '16 at 18:22
• @Flimm updated. – Jet Blue Apr 21 '16 at 18:43

Today i deep in State Design Pattern. I did and tested ThreadState, which equal (+/-) to Threading in C#, as described in picture from Threading in C#

You can easly add new states, configure moves from one state to other is very easy becouse it incapsulated in state implementation

Implementation and using at: Implements .NET ThreadState by State Design Pattern

• Link is dead. Do you have another? – rolls Aug 27 '17 at 1:43
• Archived link here: archive.is/z4yQ1 – rolls Aug 27 '17 at 1:43

I haven't tried implementing a FSM in C# yet, but these all sound (or look) very complicated to the way I handled FSM's in the past in low-level languages like C or ASM.

I believe the method I've always known is called something like an "Iterative Loop". In it, you essentially have a 'while' loop that periodically exits based on events (interrupts), then returns to the main loop again.

Within the interrupt handlers, you would pass a CurrentState and return a NextState, which then overwrites the CurrentState variable in the main loop. You do this ad infinitum until the program closes (or the microcontroller resets).

What I'm seeing other answers all look very complicated compared with how a FSM is, in my mind, intended to be implemented; its beauty lies in its simplicity and FSM can be very complicated with many, many states and transitions, but they allow complicated process to be easily broken down and digested.

I realize my response shouldn't include another question, but I am forced to ask: why do these other proposed solutions appear to be so complicated?
They seem to be akin to hitting a small nail with a giant sledge hammer.

• Completely agree. A simple while loop with a switch statement is as simple as you can get. – rolls Aug 27 '17 at 0:11
• Unless you have a very complicated state machine with many states and conditions, where you would end up with multiple nested switches. Also there might be a penalty in busy-waiting, depending on your loop implementation. – Sune Rievers Sep 26 '17 at 7:04

What a bout StatePattern. Does that fit your needs?

I think its context related, but its worth a shot for sure.

http://en.wikipedia.org/wiki/State_pattern

This let your states decide where to go and not the "object" class.

Bruno

• The state pattern deals with a class that can act differently based on the state/mode it is in, it does not deal with transition between states. – Eli Algranti Dec 12 '13 at 23:31

I've just contributed this:

Here's one of the examples demoing direct and indirect sending of commands, with states as IObserver(of signal), thus responders to a signal source, IObservable(of signal):

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace Test
{
using Machines;

{
// Enum type for the transition triggers (instead of System.String) :
public enum TvOperation { Plug, SwitchOn, SwitchOff, Unplug, Dispose }

// The state machine class type is also used as the type for its possible states constants :
public class Television : NamedState<Television, TvOperation, DateTime>
{
// Declare all the possible states constants :
public static readonly Television Unplugged = new Television("(Unplugged TV)");
public static readonly Television Off = new Television("(TV Off)");
public static readonly Television On = new Television("(TV On)");
public static readonly Television Disposed = new Television("(Disposed TV)");

// For convenience, enter the default start state when the parameterless constructor executes :
public Television() : this(Television.Unplugged) { }

// To create a state machine instance, with a given start state :
private Television(Television value) : this(null, value) { }

// To create a possible state constant :
private Television(string moniker) : this(moniker, null) { }

private Television(string moniker, Television value)
{
if (moniker == null)
{
// Build the state graph programmatically
// (instead of declaratively via custom attributes) :
Handler<Television, TvOperation, DateTime> stateChangeHandler = StateChange;
Build
(
new[]
{
new { From = Television.Unplugged, When = TvOperation.Plug, Goto = Television.Off, With = stateChangeHandler },
new { From = Television.Unplugged, When = TvOperation.Dispose, Goto = Television.Disposed, With = stateChangeHandler },
new { From = Television.Off, When = TvOperation.SwitchOn, Goto = Television.On, With = stateChangeHandler },
new { From = Television.Off, When = TvOperation.Unplug, Goto = Television.Unplugged, With = stateChangeHandler },
new { From = Television.Off, When = TvOperation.Dispose, Goto = Television.Disposed, With = stateChangeHandler },
new { From = Television.On, When = TvOperation.SwitchOff, Goto = Television.Off, With = stateChangeHandler },
new { From = Television.On, When = TvOperation.Unplug, Goto = Television.Unplugged, With = stateChangeHandler },
new { From = Television.On, When = TvOperation.Dispose, Goto = Television.Disposed, With = stateChangeHandler }
},
false
);
}
else
// Name the state constant :
Moniker = moniker;
Start(value ?? this);
}

// Because the states' value domain is a reference type, disallow the null value for any start state value :
protected override void OnStart(Television value)
{
if (value == null)
throw new ArgumentNullException("value", "cannot be null");
}

// When reaching a final state, unsubscribe from all the signal source(s), if any :
protected override void OnComplete(bool stateComplete)
{
// Holds during all transitions into a final state
// (i.e., stateComplete implies IsFinal) :
System.Diagnostics.Debug.Assert(!stateComplete || IsFinal);

if (stateComplete)
UnsubscribeFromAll();
}

// Executed before and after every state transition :
private void StateChange(IState<Television> state, ExecutionStep step, Television value, TvOperation info, DateTime args)
{
// Holds during all possible transitions defined in the state graph
// (i.e., (step equals ExecutionStep.LeaveState) implies (not state.IsFinal))
System.Diagnostics.Debug.Assert((step != ExecutionStep.LeaveState) || !state.IsFinal);

// Holds in instance (i.e., non-static) transition handlers like this one :
System.Diagnostics.Debug.Assert(this == state);

switch (step)
{
case ExecutionStep.LeaveState:
var timeStamp = ((args != default(DateTime)) ? String.Format("\t\t(@ {0})", args) : String.Empty);
Console.WriteLine();
// 'value' is the state value that we are transitioning TO :
Console.WriteLine("\tLeave :\t{0} -- {1} -> {2}{3}", this, info, value, timeStamp);
break;
case ExecutionStep.EnterState:
// 'value' is the state value that we have transitioned FROM :
Console.WriteLine("\tEnter :\t{0} -- {1} -> {2}", value, info, this);
break;
default:
break;
}
}

public override string ToString() { return (IsConstant ? Moniker : Value.ToString()); }
}

public static void Run()
{
Console.Clear();

// Create a signal source instance (here, a.k.a. "remote control") that implements
// IObservable<TvOperation> and IObservable<KeyValuePair<TvOperation, DateTime>> :
var remote = new SignalSource<TvOperation, DateTime>();

// Create a television state machine instance (automatically set in a default start state),
// and make it subscribe to a compatible signal source, such as the remote control, precisely :
var tv = new Television().Using(remote);
bool done;

// Always holds, assuming the call to Using(...) didn't throw an exception (in case of subscription failure) :
System.Diagnostics.Debug.Assert(tv != null, "There's a bug somewhere: this message should never be displayed!");

// As commonly done, we can trigger a transition directly on the state machine :
tv.MoveNext(TvOperation.Plug, DateTime.Now);

// Alternatively, we can also trigger transitions by emitting from the signal source / remote control
// that the state machine subscribed to / is an observer of :
remote.Emit(TvOperation.SwitchOn, DateTime.Now);
remote.Emit(TvOperation.SwitchOff);
remote.Emit(TvOperation.SwitchOn);
remote.Emit(TvOperation.SwitchOff, DateTime.Now);

done =
(
tv.
MoveNext(TvOperation.Unplug).
MoveNext(TvOperation.Dispose) // MoveNext(...) returns null iff tv.IsFinal == true
== null
);

remote.Emit(TvOperation.Unplug); // Ignored by the state machine thanks to the OnComplete(...) override above

Console.WriteLine();
Console.WriteLine("Is the TV's state '{0}' a final state? {1}", tv.Value, done);

Console.WriteLine();
Console.WriteLine("Press any key...");
}
}
}


Note : this example is rather artificial and mostly meant to demo a number of orthogonal features. There should seldomly be a real need to implement the state value domain itself by a full blown class, using the CRTP ( see : http://en.wikipedia.org/wiki/Curiously_recurring_template_pattern ) like this.

Here's for a certainly simpler and likely much more common implementation use case (using a simple enum type as the states value domain), for the same state machine, and with the same test case :

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace Test
{
using Machines;

public static class WatchingTvSample
{
public enum Status { Unplugged, Off, On, Disposed }

public class DeviceTransitionAttribute : TransitionAttribute
{
public Status From { get; set; }
public string When { get; set; }
public Status Goto { get; set; }
public object With { get; set; }
}

// State<Status> is a shortcut for / derived from State<Status, string>,
// which in turn is a shortcut for / derived from State<Status, string, object> :
public class Device : State<Status>
{
// Executed before and after every state transition :
protected override void OnChange(ExecutionStep step, Status value, string info, object args)
{
if (step == ExecutionStep.EnterState)
{
// 'value' is the state value that we have transitioned FROM :
Console.WriteLine("\t{0} -- {1} -> {2}", value, info, this);
}
}

public override string ToString() { return Value.ToString(); }
}

// Since 'Device' has no state graph of its own, define one for derived 'Television' :
[DeviceTransition(From = Status.Unplugged, When = "Plug", Goto = Status.Off)]
[DeviceTransition(From = Status.Unplugged, When = "Dispose", Goto = Status.Disposed)]
[DeviceTransition(From = Status.Off, When = "Switch On", Goto = Status.On)]
[DeviceTransition(From = Status.Off, When = "Unplug", Goto = Status.Unplugged)]
[DeviceTransition(From = Status.Off, When = "Dispose", Goto = Status.Disposed)]
[DeviceTransition(From = Status.On, When = "Switch Off", Goto = Status.Off)]
[DeviceTransition(From = Status.On, When = "Unplug", Goto = Status.Unplugged)]
[DeviceTransition(From = Status.On, When = "Dispose", Goto = Status.Disposed)]
public class Television : Device { }

public static void Run()
{
Console.Clear();

// Create a television state machine instance, and return it, set in some start state :
var tv = new Television().Start(Status.Unplugged);
bool done;

// Holds iff the chosen start state isn't a final state :
System.Diagnostics.Debug.Assert(tv != null, "The chosen start state is a final state!");

// Trigger some state transitions with no arguments
// ('args' is ignored by this state machine's OnChange(...), anyway) :
done =
(
tv.
MoveNext("Plug").
MoveNext("Switch On").
MoveNext("Switch Off").
MoveNext("Switch On").
MoveNext("Switch Off").
MoveNext("Unplug").
MoveNext("Dispose") // MoveNext(...) returns null iff tv.IsFinal == true
== null
);

Console.WriteLine();
Console.WriteLine("Is the TV's state '{0}' a final state? {1}", tv.Value, done);

Console.WriteLine();
Console.WriteLine("Press any key...");
}
}
}


'HTH

• Isn't it a bit strange that each state instance has its own copy of the state graph? – Groo May 11 '14 at 22:02
• @Groo : no, they don't. Only the instances of Television constructed using the private constructor with a null string for the moniker (hence, calling the protected 'Build' method) will have a state graph, as state machines. The others, named instances of Television (with a moniker not null for that conventional and ad-hoc purpose) will be mere "fix point" states (so to speak), serving as the state constants (that the state graph(s) of actual state machines will reference as their vertices). 'HTH, – YSharp May 11 '14 at 22:08
• Ok, I get it. Anyway, IMHO, it would've been better if you have included some code which actually handles these transitions. This way, it only serves as an example of using a (IMHO) not-so-obvious interface for your library. For example, how is StateChange resolved? Through Reflection? Is that really necessary? – Groo May 11 '14 at 22:33
• @Groo : Good remark. It isn't necessary indeed to reflect on the handler in that first example because it's done programmatically in there precisely and can be statically bound/type checked (unlike when via custom attributes). So this work as expected too: private Television(string moniker, Television value) { Handler<Television, TvOperation, DateTime> myHandler = StateChange; // (code omitted) new { From = Television.Unplugged, When = TvOperation.Plug, Goto = Television.Off, With = myHandler } } – YSharp May 11 '14 at 22:54
• Thanks for your effort! – Groo May 12 '14 at 9:19

I made this generic state machine out of Juliet's code. It's working awesome for me.

These are the benefits:

• you can create new state machine in code with two enums TState and TCommand,
• added struct TransitionResult<TState> to have more control over the output results of [Try]GetNext() methods
• exposing nested class StateTransition only through AddTransition(TState, TCommand, TState) making it easier to work with it

Code:

public class StateMachine<TState, TCommand>
where TState : struct, IConvertible, IComparable
where TCommand : struct, IConvertible, IComparable
{
protected class StateTransition<TS, TC>
where TS : struct, IConvertible, IComparable
where TC : struct, IConvertible, IComparable
{

public StateTransition(TS currentState, TC command)
{
if (!typeof(TS).IsEnum || !typeof(TC).IsEnum)
{
throw new ArgumentException("TS,TC must be an enumerated type");
}

CurrentState = currentState;
Command = command;
}

public override int GetHashCode()
{
return 17 + 31 * CurrentState.GetHashCode() + 31 * Command.GetHashCode();
}

public override bool Equals(object obj)
{
StateTransition<TS, TC> other = obj as StateTransition<TS, TC>;
return other != null
&& this.CurrentState.CompareTo(other.CurrentState) == 0
&& this.Command.CompareTo(other.Command) == 0;
}
}

private Dictionary<StateTransition<TState, TCommand>, TState> transitions;
public TState CurrentState { get; private set; }

protected StateMachine(TState initialState)
{
if (!typeof(TState).IsEnum || !typeof(TCommand).IsEnum)
{
throw new ArgumentException("TState,TCommand must be an enumerated type");
}

CurrentState = initialState;
transitions = new Dictionary<StateTransition<TState, TCommand>, TState>();
}

/// <summary>
/// Defines a new transition inside this state machine
/// </summary>
/// <param name="start">source state</param>
/// <param name="command">transition condition</param>
/// <param name="end">destination state</param>
protected void AddTransition(TState start, TCommand command, TState end)
{
}

public TransitionResult<TState> TryGetNext(TCommand command)
{
StateTransition<TState, TCommand> transition = new StateTransition<TState, TCommand>(CurrentState, command);
TState nextState;
if (transitions.TryGetValue(transition, out nextState))
return new TransitionResult<TState>(nextState, true);
else
return new TransitionResult<TState>(CurrentState, false);
}

public TransitionResult<TState> MoveNext(TCommand command)
{
var result = TryGetNext(command);
if(result.IsValid)
{
//changes state
CurrentState = result.NewState;
}
return result;
}
}


This is the return type of TryGetNext method:

public struct TransitionResult<TState>
{
public TransitionResult(TState newState, bool isValid)
{
NewState = newState;
IsValid = isValid;
}
public TState NewState;
public bool IsValid;
}


## How to use:

This is how you can create a OnlineDiscountStateMachine from the generic class:

Define an enum OnlineDiscountState for its states and an enum OnlineDiscountCommand for its commands.

Define a class OnlineDiscountStateMachine derived from the generic class using those two enums

Derive the constructor from base(OnlineDiscountState.InitialState) so that the initial state is set to OnlineDiscountState.InitialState

Use AddTransition as many times as needed

public class OnlineDiscountStateMachine : StateMachine<OnlineDiscountState, OnlineDiscountCommand>
{
public OnlineDiscountStateMachine() : base(OnlineDiscountState.Disconnected)
{
}
}


use the derived state machine

    odsm = new OnlineDiscountStateMachine();
public void Connect()
{
var result = odsm.TryGetNext(OnlineDiscountCommand.Connect);

//is result valid?
if (!result.IsValid)
//if this happens you need to add transitions to the state machine
//in this case result.NewState is the same as before
Console.WriteLine("cannot navigate from this state using OnlineDiscountCommand.Connect");

//the transition was successfull
//show messages for new states
else if(result.NewState == OnlineDiscountState.Error_AuthenticationError)
Console.WriteLine("invalid user/pass");
else if(result.NewState == OnlineDiscountState.Connected)
Console.WriteLine("Connected");
else
Console.WriteLine("not implemented transition result for " + result.NewState);
}


In my opinion a state machine is not only meant for changing states but also (very important) for handling triggers/events within a specific state. If you want to understand state machine design pattern better, a good description can be found within the book Head First Design Patterns, page 320.

It is not only about the states within variables but also about handling triggers within the different states. Great chapter (and no, there is no fee for me in mentioning this :-) which contains just an easy to understand explanation.

I think the state machine proposed by Juliet has a mistake: the method GetHashCode can return the same hash code for two different transitions, for example:

State = Active (1) , Command = Pause (2) => HashCode = 17 + 31 + 62 = 110

State = Paused (2) , Command = End (1) => HashCode = 17 + 62 + 31 = 110

To avoid this error, the method should be like this:

public override int GetHashCode()
{
return 17 + 23 * CurrentState.GetHashCode() + 31 * Command.GetHashCode();
}


Alex

• Hash code is not required to return a unique number for any possible combination, only a distinct value with good distribution across the target range (in this case the range is the all the possible int values). That's why HashCode is always implemented along with Equals. If hash codes are the same, then the objects are checked for exact eqaulity using the Equals method. – Dmitry Avtonomov Jul 13 '18 at 5:22

FiniteStateMachine is a Simple State Machine, written in C# Link

Advantages tu use my library FiniteStateMachine:

1. Define a "context" class to present a single interface to the outside world.
2. Define a State abstract base class.
3. Represent the different "states" of the state machine as derived classes of the State base class.
4. Define state-specific behavior in the appropriate State derived classes.
5. Maintain a pointer to the current "state" in the "context" class.
6. To change the state of the state machine, change the current "state" pointer.

void Main()
{
var machine = new SFM.Machine(new StatePaused());
var output = machine.Command("Input_Start", Command.Start);
Console.WriteLine(Command.Start.ToString() + "->  State: " + machine.Current);
Console.WriteLine(output);

output = machine.Command("Input_Pause", Command.Pause);
Console.WriteLine(Command.Pause.ToString() + "->  State: " + machine.Current);
Console.WriteLine(output);
Console.WriteLine("-------------------------------------------------");
}
public enum Command
{
Start,
Pause,
}

public class StateActive : SFM.State
{

public override void Handle(SFM.IContext context)

{
//Gestione parametri
var input = (String)context.Input;
context.Output = input;

//Gestione Navigazione
if ((Command)context.Command == Command.Pause) context.Next = new StatePaused();
if ((Command)context.Command == Command.Start) context.Next = this;

}
}

public class StatePaused : SFM.State
{

public override void Handle(SFM.IContext context)

{

//Gestione parametri
var input = (String)context.Input;
context.Output = input;

//Gestione Navigazione
if ((Command)context.Command == Command.Start) context.Next = new  StateActive();
if ((Command)context.Command == Command.Pause) context.Next = this;

}

}

• It has GNU GPL license. – Der_Meister Mar 16 '17 at 5:09

I would recommend state.cs. I personally used state.js (the JavaScript version) and am very happy with it. That C# version works in a similar way.

You instantiate states:

        // create the state machine
var player = new StateMachine<State>( "player" );

// create some states
var initial = player.CreatePseudoState( "initial", PseudoStateKind.Initial );
var operational = player.CreateCompositeState( "operational" );
...


You instantiate some transitions:

        var t0 = player.CreateTransition( initial, operational );
player.CreateTransition( history, stopped );
player.CreateTransition<String>( stopped, running, ( state, command ) => command.Equals( "play" ) );
player.CreateTransition<String>( active, stopped, ( state, command ) => command.Equals( "stop" ) );


You define actions on states and transitions:

    t0.Effect += DisengageHead;
t0.Effect += StopMotor;


And that's (pretty much) it. Look at the website for more information.

There are 2 popular state machine packages in NuGet.

The Appccelerate lib has good documentation, but it does not support .NET 4, so I chose StateMachineToolkit for my project.

Other alternative in this repo https://github.com/lingkodsoft/StateBliss used fluent syntax, supports triggers.

    public class BasicTests
{
[Fact]
public void Tests()
{
// Arrange
StateMachineManager.Register(new [] { typeof(BasicTests).Assembly }); //Register at bootstrap of your application, i.e. Startup
var currentState = AuthenticationState.Unauthenticated;
var nextState = AuthenticationState.Authenticated;
var data = new Dictionary<string, object>();

// Act
var changeInfo = StateMachineManager.Trigger(currentState, nextState, data);

// Assert
Assert.True(changeInfo.StateChangedSucceeded);
Assert.Equal("ChangingHandler1", changeInfo.Data["key1"]);
Assert.Equal("ChangingHandler2", changeInfo.Data["key2"]);
}

//this class gets regitered automatically by calling StateMachineManager.Register
public class AuthenticationStateDefinition : StateDefinition<AuthenticationState>
{
public override void Define(IStateFromBuilder<AuthenticationState> builder)
{
builder.From(AuthenticationState.Unauthenticated).To(AuthenticationState.Authenticated)
.Changing(this, a => a.ChangingHandler1)
.Changed(this, a => a.ChangedHandler1);

builder.OnEntering(AuthenticationState.Authenticated, this, a => a.OnEnteringHandler1);
builder.OnEntered(AuthenticationState.Authenticated, this, a => a.OnEnteredHandler1);

builder.OnExiting(AuthenticationState.Unauthenticated, this, a => a.OnExitingHandler1);
builder.OnExited(AuthenticationState.Authenticated, this, a => a.OnExitedHandler1);

builder.OnEditing(AuthenticationState.Authenticated, this, a => a.OnEditingHandler1);
builder.OnEdited(AuthenticationState.Authenticated, this, a => a.OnEditedHandler1);

builder.ThrowExceptionWhenDiscontinued = true;
}

private void ChangingHandler1(StateChangeGuardInfo<AuthenticationState> changeinfo)
{
var data = changeinfo.DataAs<Dictionary<string, object>>();
data["key1"] = "ChangingHandler1";
}

private void OnEnteringHandler1(StateChangeGuardInfo<AuthenticationState> changeinfo)
{
// changeinfo.Continue = false; //this will prevent changing the state
}

private void OnEditedHandler1(StateChangeInfo<AuthenticationState> changeinfo)
{
}

private void OnExitedHandler1(StateChangeInfo<AuthenticationState> changeinfo)
{
}

private void OnEnteredHandler1(StateChangeInfo<AuthenticationState> changeinfo)
{
}

private void OnEditingHandler1(StateChangeGuardInfo<AuthenticationState> changeinfo)
{
}

private void OnExitingHandler1(StateChangeGuardInfo<AuthenticationState> changeinfo)
{
}

private void ChangedHandler1(StateChangeInfo<AuthenticationState> changeinfo)
{
}
}

public class AnotherAuthenticationStateDefinition : StateDefinition<AuthenticationState>
{
public override void Define(IStateFromBuilder<AuthenticationState> builder)
{
builder.From(AuthenticationState.Unauthenticated).To(AuthenticationState.Authenticated)
.Changing(this, a => a.ChangingHandler2);

}

private void ChangingHandler2(StateChangeGuardInfo<AuthenticationState> changeinfo)
{
var data = changeinfo.DataAs<Dictionary<string, object>>();
data["key2"] = "ChangingHandler2";
}
}
}

public enum AuthenticationState
{
Unauthenticated,
Authenticated
}
}