## TL;DR

An inductive invariant of this program, in TLA+ syntax, is:

```
/\ \A i \in 0..N-1 : (pc[i] \in {"s2", "Done"} => x[i] = 1)
/\ (\A i \in 0..N-1 : pc[i] = "Done") => \E i \in 0..N-1 : y[i] = 1
```

## What is an inductive invariant?

An inductive invariant is an invariant that satisfies the following two
conditions:

```
Init => Inv
Inv /\ Next => Inv'
```

where:

`Inv`

is the inductive invariant
`Init`

is the predicate that describes the initial state
`Next`

is the predicate that describes state transitions.

## Why use inductive invariants?

Note that an inductive invariant is only about current state and next state. It
makes no references to the execution history,
it's not about the past behavior of the system.

In section 7.2.1 of Principles and Specifications of Concurrent Systems
(generally known as The TLA+ Hyperbook),
Lamport describes why he prefers using inductive invariants over behavioral
proofs (i.e., those that make reference to execution history).

Behavioral proofs can be made more formal, but I don’t know any practical way
to make them completely formal—that is, to write executable descriptions of
real algorithms and formal behavioral proofs that they satisfy correctness
properties. This is one reason why, in more than 35 years of writing
concurrent algorithms, I have found behavioral reasoning to be unreliable for
more complicated algorithms. I believe another reason to be that behavioral
proofs are inherently more complex than state-based ones for sufficiently
complex algorithms. This leads people to write less rigorous behavioral
proofs for those algorithms—especially with no completely formal proofs to
serve as guideposts.

To avoid mistakes, we have to think in terms of states,
not in terms of executions... Still, behavioral reasoning provides a
different way of thinking about an algorithm, and thinking is always helpful.
Behavioral reasoning is bad only if it is used instead of state-based
reasoning rather than in addition to it.

## Some preliminaries

The property we are interested in proving is (in TLA+ syntax):

```
(\A i \in 0..N-1 : pc[i] = "Done") => \E i \in 0..N-1 : y[i] = 1
```

Here I'm using the PlusCal convention of describing the control state of each
process using a variable named "pc" (I think of it as "program counter").

This property is an invariant, but it's not an inductive invariant, because it
doesn't satisfy the conditions above.

You can use an inductive invariant to prove a property by writing a proof that look like this:

```
1. Init => Inv
2. Inv /\ Next => Inv'
3. Inv => DesiredProperty
```

To come up with an inductive invariant, we need to give labels to each step of
the algorithm, let's call them "s1", "s2", and "Done", where "Done" is the
terminal state for each process.

```
s1: x[self] := 1;
s2: y[self] := x[(self-1) % N]
```

## Coming up with an inductive invariant

Consider the state of the program when it is in the penultimate (second-to-last) state of an
execution.

In the last execution state, `pc[i]="Done"`

for all values of i. In the
penultimate state, `pc[i]="Done"`

for all values of i except one, let's call it
j, where `pc[j]="s2"`

.

If a process i is in the "Done" state, then it must be true that `x[i]=1`

, since the process must have executed statement "s1".
Similarly, the process j that is in the state "s2" must also have executed
statement "s1", so it must be true that `x[j]=1`

.

We can express this as an invariant, which happens to be an inductive
invariant.

```
\A i \in 0..N-1 : (pc[i] \in {"s2", "Done"} => x[i] = 1)
```

## PlusCal model

To prove that our invariant is an inductive invariant, we need a proper model that has an
`Init`

state predicate and a `Next`

state predicate.

We can start by describing the algorithm in PlusCal. It's a very simple
algorithm, so I'll call it "Simple".

```
--algorithm Simple
variables
x = [i \in 0..N-1 |->0];
y = [i \in 0..N-1 |->0];
process Proc \in 0..N-1
begin
s1: x[self] := 1;
s2: y[self] := x[(self-1) % N]
end process
end algorithm
```

## Translating to TLA+

We can translate the PlusCal model into TLA+. Here's what it looks like when we
translate PlusCal into TLA+ (I've left out the termination condition, because
we don't need it here).

```
------------------------------- MODULE Simple -------------------------------
EXTENDS Naturals
CONSTANTS N
VARIABLES x, y, pc
vars == << x, y, pc >>
ProcSet == (0..N-1)
Init == (* Global variables *)
/\ x = [i \in 0..N-1 |->0]
/\ y = [i \in 0..N-1 |->0]
/\ pc = [self \in ProcSet |-> "s1"]
s1(self) == /\ pc[self] = "s1"
/\ x' = [x EXCEPT ![self] = 1]
/\ pc' = [pc EXCEPT ![self] = "s2"]
/\ y' = y
s2(self) == /\ pc[self] = "s2"
/\ y' = [y EXCEPT ![self] = x[(self-1) % N]]
/\ pc' = [pc EXCEPT ![self] = "Done"]
/\ x' = x
Proc(self) == s1(self) \/ s2(self)
Next == (\E self \in 0..N-1: Proc(self))
\/ (* Disjunct to prevent deadlock on termination *)
((\A self \in ProcSet: pc[self] = "Done") /\ UNCHANGED vars)
Spec == Init /\ [][Next]_vars
=============================================================================
```

Note how it defines the `Init`

and `Next`

state predicates.

## The inductive invariant in TLA+

We can now specify the inductive invariant we want to prove. We also want our
inductive invariant to imply the property we're interested in proving, so we
add it as a conjunction.

```
Inv == /\ \A i \in 0..N-1 : (pc[i] \in {"s2", "Done"} => x[i] = 1)
/\ (\A i \in 0..N-1 : pc[i] = "Done") => \E i \in 0..N-1 : y[i] = 1
```

## Informal handwaving "proof"

### 1. `Init => Inv`

It should be obvious why this is true, since the antecedents in `Inv`

are all false if `Init`

is true.

### 2. `Inv /\ Next => Inv'`

The first conjunct of Inv'

```
(\A i \in 0..N-1 : (pc[i] \in {"s2", "Done"} => x[i] = 1))'
```

The interesting case is the one where `pc[i]="s1"`

and `pc'[i]="s2"`

for some i. By
the definition of `s1`

, it should be clear why this is true.

The second conjunct of Inv'

```
((\A i \in 0..N-1 : pc[i] = "Done") => \E i \in 0..N-1 : y[i] = 1)'
```

The interesting case is the one we discussed earlier, where `pc[i]="Done"`

for
all values of i except one, j, where `pc[j]="s2"`

.

By the first conjunct of Inv, we know that `x[i]=1`

for all values of i.

By `s2`

, `y'[j]=1`

.

### 3. `Inv => DesiredProperty`

Here, our desired property is

```
(\A i \in 0..N-1 : pc[i] = "Done") => \E i \in 0..N-1 : y[i] = 1
```

Note that we've just anded the property that we are interested in to the
invariant, so this is trivial to prove.

## Formal proof with TLAPS

You can use the TLA+ Proof
System (TLAPS) to write
a formal proof that can be checked mechanically to determine if it is correct.

Here's a proof that I wrote and verified using TLAPS that uses an inductive invariant to
prove the desired property. (Note: this is the first proof I've ever written
using TLAPS, so keep in mind this has been written by a novice).

```
AtLeastOneYWhenDone == (\A i \in 0..N-1 : pc[i] = "Done") => \E i \in 0..N-1 : y[i] = 1
TypeOK == /\ x \in [0..N-1 -> {0,1}]
/\ y \in [0..N-1 -> {0,1}]
/\ pc \in [ProcSet -> {"s1", "s2", "Done"}]
Inv == /\ TypeOK
/\ \A i \in 0..N-1 : (pc[i] \in {"s2", "Done"} => x[i] = 1)
/\ AtLeastOneYWhenDone
ASSUME NIsInNat == N \in Nat \ {0}
\* TLAPS doesn't know this property of modulus operator
AXIOM ModInRange == \A i \in 0..N-1: (i-1) % N \in 0..N-1
THEOREM Spec=>[]AtLeastOneYWhenDone
<1> USE DEF ProcSet, Inv
<1>1. Init => Inv
BY NIsInNat DEF Init, Inv, TypeOK, AtLeastOneYWhenDone
<1>2. Inv /\ [Next]_vars => Inv'
<2> SUFFICES ASSUME Inv,
[Next]_vars
PROVE Inv'
OBVIOUS
<2>1. CASE Next
<3>1. CASE \E self \in 0..N-1: Proc(self)
<4> SUFFICES ASSUME NEW self \in 0..N-1,
Proc(self)
PROVE Inv'
BY <3>1
<4>1. CASE s1(self)
BY <4>1, NIsInNat DEF s1, TypeOK, AtLeastOneYWhenDone
<4>2. CASE s2(self)
BY <4>2, NIsInNat, ModInRange DEF s2, TypeOK, AtLeastOneYWhenDone
<4>3. QED
BY <3>1, <4>1, <4>2 DEF Proc
<3>2. CASE (\A self \in ProcSet: pc[self] = "Done") /\ UNCHANGED vars
BY <3>2 DEF TypeOK, vars, AtLeastOneYWhenDone
<3>3. QED
BY <2>1, <3>1, <3>2 DEF Next
<2>2. CASE UNCHANGED vars
BY <2>2 DEF TypeOK, vars, AtLeastOneYWhenDone
<2>3. QED
BY <2>1, <2>2
<1>3. Inv => AtLeastOneYWhenDone
OBVIOUS
<1>4. QED
BY <1>1, <1>2, <1>3, PTL DEF Spec
```

Note that in a proof using TLAPS, you need to have a type checking invariant (it's called `TypeOK`

above), and you also need to handle "stuttering states" where none of the variables change, which is why we use `[Next]_vars`

instead of `Next`

.

Here's a gist with the complete model and proof.