639 lines
31 KiB
Markdown
639 lines
31 KiB
Markdown
---
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title: "A Verified Evaluator for the Untyped Concatenative Calculus"
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date: 2021-11-27T20:24:57-08:00
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tags: ["Dawn", "Coq", "Programming Languages"]
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---
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Earlier, I wrote [an article]({{< relref "./coq_dawn" >}}) in which I used Coq to
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encode the formal semantics of [Dawn's Untyped Concatenative Calculus](https://www.dawn-lang.org/posts/foundations-ucc/),
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and to prove a few things about the mini-language. Though I'm quite happy with how that turned out,
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my article was missing something that's present on the original Dawn page -- an evaluator. In this article, I'll define
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an evaluator function in Coq, prove that it's equivalent to Dawn's formal semantics,
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and extract all of this into usable Haskell code.
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### Changes Since Last Time
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In trying to write and verify this evaluator, I decided to make changes to the way I formalized
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the UCC. Remember how we used a predicate, `IsValue`, to tag expressions that were values?
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It turns out that this is a very cumbersome approach. For one thing, this formalization
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allows for the case in which the exact same expression is a value for two different
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reasons. Although `IsValue` has only one constructor (`Val_quote`), it's actually
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{{< sidenote "right" "hott-note" "not provable" >}}
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Interestingly, it's also not provable that any two proofs of \(a = b\) are equal,
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even though equality only has one constructor, \(\text{refl}\ :\ a \rightarrow (a = a) \).
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Under the <a href="https://homotopytypetheory.org/book/">homotopic interpretation</a>
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of type theory, this corresponds to the fact that two paths from \(a\) to \(b\) need
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not be homotopic (continuously deformable) to each other.<br>
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<br>
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As an intuitive example, imagine wrapping a string around a pole. Holding the ends of
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the string in place, there's nothing you can do to "unwrap" the string. This string
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is thus not deformable into a string that starts and stops at the same points,
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but does not go around the pole.
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{{< /sidenote >}}
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that any two proofs of `IsValue e` are equal. I ended up getting into a lot of losing
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arguments with the Coq runtime about whether or not two stacks are actually the same.
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Also, some of the semantic rules expected a value on the stack with a particular proof
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for `IsValue`, and rejected the exact same stack with a generic value.
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Thus, I switched from our old implementation:
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{{< codelines "Coq" "dawn/Dawn.v" 19 22 >}}
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To the one I originally had in mind:
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{{< codelines "Coq" "dawn/DawnV2.v" 19 19 >}}
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I then had the following function to convert a value back into an equivalent expression:
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{{< codelines "Coq" "dawn/DawnV2.v" 22 25 >}}
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I replaced instances of `projT1` with instances of `value_to_expr`.
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### Where We Are
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At the end of my previous article, we ended up with a Coq encoding of the big-step
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[operational semantics](https://en.wikipedia.org/wiki/Operational_semantics)
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of UCC, as well as some proofs of correctness about the derived forms from
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the article (like \(\text{quote}_3\) and \(\text{rotate}_3\)). The trouble
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is, despite having our operational semantics, we can't make our Coq
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code run anything. This is for several reasons:
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1. Our definitions only let us to _confirm_ that given some
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initial stack, a program ends up in some other final stack. We even have a
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little `Ltac2` tactic to help us automate this kind of proof. However, in an evaluator,
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the final stack is not known until the program finishes running. We can't
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confirm the result of evaluation, we need to _find_ it.
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2. To address the first point, we could try write a function that takes a program
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and an initial stack, and produces a final stack, as well as a proof that
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the program would evaluate to this stack under our semantics. However,
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it's quite easy to write a non-terminating UCC program, whereas functions
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in Coq _have to terminate!_ We can't write a terminating function to
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run non-terminating code.
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So, is there anything we can do? No, there isn't. Writing an evaluator in Coq
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is just not possible. The end, thank you for reading.
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Just kidding -- there's definitely a way to get our code evaluating, but it
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will look a little bit strange.
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### A Step-by-Step Evaluator
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The trick is to recognize that program evaluation
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occurs in steps. There may well be an infinite number of steps, if the program
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is non-terminating, but there's always a step we can take. That is, unless
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an invalid instruction is run, like trying to clone from an empty stack, or unless
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the program finished running. You don't need a non-terminating function to just
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give you a next step, if one exists. We can write such a function in Coq.
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Here's a new data type that encodes the three situations we mentioned in the
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previous paragraph. Its constructors (one per case) are as follows:
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1. `err` - there are no possible evaluation steps due to an error.
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3. `middle e s` - the evaluation took a step; the stack changed to `s`, and the rest of the program is `e`.
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2. `final s` - there are no possible evaluation steps because the evaluation is complete,
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leaving a final stack `s`.
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{{< codelines "Coq" "dawn/DawnEval.v" 6 9 >}}
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We can now write a function that tries to execute a single step given an expression.
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{{< codelines "Coq" "dawn/DawnEval.v" 11 27 >}}
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Most intrinsics, by themselves, complete after just one step. For instance, a program
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consisting solely of \(\text{swap}\) will either fail (if the stack doesn't have enough
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values), or it will swap the top two values and be done. We list only "correct" cases,
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and resort to a "catch-all" case on line 26 that returns an error. The one multi-step
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intrinsic is \(\text{apply}\), which can evaluate an arbitrary expression from the stack.
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In this case, the "one step" consists of popping the quoted value from the stack; the
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"remaining program" is precisely the expression that was popped.
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Quoting an expression also always completes in one step (it simply places the quoted
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expression on the stack). The really interesting case is composition. Expressions
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are evaluated left-to-right, so we first determine what kind of step the left expression (`e1`)
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can take. We may need more than one step to finish up with `e1`, so there's a good chance it
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returns a "rest program" `e1'` and a stack `vs'`. If this happens, to complete evaluation of
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\(e_1\ e_2\), we need to first finish evaluating \(e_1'\), and then evaluate \(e_2\).
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Thus, the "rest of the program" is \(e_1'\ e_2\), or `e_comp e1' e2`. On the other hand,
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if `e1` finished evaluating, we still need to evaluate `e2`, so our "rest of the program"
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is \(e_2\), or `e2`. If evaluating `e1` led to an error, then so did evaluating `e_comp e1 e2`,
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and we return `err`.
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### Extracting Code
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Just knowing a single step is not enough to run the code. We need something that repeatedly
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tries to take a step, as long as it's possible. However, this part is once again
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not possible in Coq, as it brings back the possibility of non-termination. So if we can't use
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Coq, why don't we use another language? Coq's extraction mechanism allows us to do just that.
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I added the following code to the end of my file:
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{{< codelines "Coq" "dawn/DawnEval.v" 231 235 >}}
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Coq happily produces a new file, `UccGen.hs` with a lot of code. It's not exactly the most
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aesthetic; here's a quick peek:
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```Haskell
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data Intrinsic =
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Swap
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| Clone
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| Drop
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| Quote
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| Compose
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| Apply
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data Expr =
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E_int Intrinsic
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| E_quote Expr
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| E_comp Expr Expr
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data Value =
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V_quote Expr
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-- ... more
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```
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All that's left is to make a new file, `Ucc.hs`. I use a different file so that
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Coq doesn't overwrite my changes every time I re-run extraction. In this
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file, we place the "glue code" that tries running one step after another:
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{{< codelines "Coq" "dawn/Ucc.hs" 46 51 >}}
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Finally, loading up GHCi using `ghci Ucc.hs`, I can run the following commands:
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```
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ghci> fromList = foldl1 E_comp
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ghci> test = eval [] $ fromList [true, false, UccGen.or]
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ghci> :f test
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test = Just [V_quote (E_comp (E_int Swap) (E_int Drop))]
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```
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That is, applying `or` to `true` and `false` results a stack with only `true` on top.
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As expected, and proven by our semantics!
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### Proving Equivalence
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Okay, so `true false or` evaluates to `true`, much like our semantics claims.
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However, does our evaluator _always_ match the semantics? So far, we have not
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claimed or verified that it does. Let's try giving it a shot.
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#### First Steps and Evaluation Chains
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The first thing we can do is show that if we have a proof that `e` takes
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initial stack `vs` to final stack `vs'`, then each
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`eval_step` "makes progress" towards `vs'` (it doesn't simply _return_
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`vs'`, since it only takes a single step and doesn't always complete
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the evaluation). We also want to show that if the semantics dictates
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`e` finishes in stack `vs'`, then `eval_step` will never return an error.
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Thus, we have two possibilities:
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* `eval_step` returns `final`. In this case, for it to match our semantics,
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the final stack must be the same as `vs'`. Here's the relevant section
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from the Coq file:
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{{< codelines "Coq" "dawn/DawnEval.v" 30 30 >}}
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* `eval_step` returns `middle`. In this case, the "rest of the program" needs
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to evaluate to `vs'` according to our semantics (otherwise, taking a step
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has changed the program's final outcome, which should not happen).
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We need to quantify the new variables (specifically, the "rest of the
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program", which we'll call `ei`, and the "stack after one step", `vsi`),
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for which we use Coq's `exists` clause. The whole relevant statement is as
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follows:
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{{< codelines "Coq" "dawn/DawnEval.v" 31 33 >}}
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The whole theorem statement is as follows:
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{{< codelines "Coq" "dawn/DawnEval.v" 29 33 >}}
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I have the Coq proof script for this (in fact, you can click the link
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at the top of the code block to view the original source file). However,
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there's something unsatisfying about this statement. In particular,
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how do we prove that an entire sequence of steps evaluates
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to something? We'd have to examine the first step, checking if
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it's a "final" step or a "middle" step; if it's a "middle" step,
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we'd have to move on to the "rest of the program" and repeat the process.
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Each time we'd have to "retrieve" `ei` and `vsi` from `eval_step_correct`,
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and feed it back to `eval_step`.
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I'll do you one better: how do we even _say_ that an expression "evaluates
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step-by-step to final stack `vs'`"? For one step, we can say:
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```Coq
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eval_step vs e = final vs'
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```
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Here's a picture so you can start visualizing what it looks like. The black line represents
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a single "step".
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{{< figure src="coq_eval_empty.png" caption="Visual representation of a single-step evaluation." class="small" alt="Two dots connected by a line. One dot is labeled \"vs\", and the other \"vs1\"." >}}
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For two steps, we'd have to assert the existence of an intermediate
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expression (the "rest of the program" after the first step):
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```Coq
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exists ei vsi,
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eval_step vs e = middle ei vsi /\ (* First step to intermediate expression. *)
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eval_step vsi ei = final vs' (* Second step to final state. *)
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```
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Once again, here's a picture. I've highlighted the intermediate state, `vsi`, in
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a brighter color.
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{{< figure src="coq_eval_one.png" caption="Visual representation of a two-step evaluation." class="small" alt="Three dots connected by lines. The first dot is labeled \"vs\", the next \"vsi\", and the last \"vs1\". The second dot is highlighted." >}}
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For three steps:
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```Coq
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exists ei1 ei2 vsi1 vsi2,
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eval_step vs e = middle ei1 vsi1 /\ (* First step to intermediate expression. *)
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eval_step vsi1 ei1 = middle ei2 vsi2 /\ (* Second intermediate step *)
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eval_step vsi2 ei2 = final vs' (* Second step to final state. *)
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```
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I can imagine that you're getting the idea, but here's one last picture:
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{{< figure src="coq_eval_two.png" caption="Visual representation of a three-step evaluation." class="small" alt="Four dots connected by lines. The first dot is labeled \"vs\", the next \"vsi1\", the one after \"vsi2\", and the last \"vs1\". The second and third dots are highlighted." >}}
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The Coq code for this is awful! Not only is this a lot of writing, but it also makes various
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sequences of steps have a different "shape". This way, we can't make
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proofs about evaluations of an _arbitrary_ number of steps. Not all is lost, though: if we squint
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a little at the last example (three steps), a pattern starts to emerge.
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First, let's re-arrange the `exists` quantifiers:
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```Coq
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exists ei1 vsi1, eval_step vs e = middle ei1 vsi1 /\ (* Cons *)
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exists ei2 vsi2, eval_step vsi1 ei1 = middle ei2 vsi2 /\ (* Cons *)
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eval_step vsi2 ei2 = final vs' (* Nil *)
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```
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If you squint at this, it kind of looks like a list! The "empty"
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part of a list is the final step, while the "cons" part is a middle step. The
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analogy holds up for another reason: an "empty" sequence has zero intermediate
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expressions, while each "cons" introduces a single new intermediate
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program.
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{{< figure src="coq_eval_lists.png" caption="Evaluation sequences as lists." class="large" alt="The three previous figures are drawn together, each next to its list representation." >}}
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Perhaps we can define a new data type that matches this? Indeed
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we can!
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{{< codelines "Coq" "dawn/DawnEval.v" 64 67 >}}
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The new data type is parameterized by the initial and final stacks, as well
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as the expression that starts in the former and ends in the latter.
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Then, consider the following _type_:
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```Coq
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eval_chain nil (e_comp (e_comp true false) or) (true :: nil)
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```
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This is the type of sequences (or chains) of steps corresponding to the
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evaluation of the program \(\text{true}\ \text{false}\ \text{or}\),
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starting in an empty stack and evaluating to a stack with only
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\(\text{true}\) on top. Thus to say that an expression evaluates to some
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final stack `vs'`, in _some unknown number of steps_, it's sufficient to write:
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```Coq
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eval_chain vs e vs'
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```
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Evaluation chains have a couple of interesting properties. First and foremost,
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they can be "concatenated". This is analogous to the `Sem_e_comp` rule
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in our original semantics: if an expression `e1` starts in stack `vs`
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and finishes in stack `vs'`, and another expression starts in stack `vs'`
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and finishes in stack `vs''`, then we can compose these two expressions,
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and the result will start in `vs` and finish in `vs''`.
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{{< codelines "Coq" "dawn/DawnEval.v" 69 75 >}}
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{{< figure src="coq_eval_chain_merge.png" caption="Merging evaluation chains." class="large" alt="Two evaluation chains, one starting in \"vs\" and ending in \"vs'\", and one starting in \"vs'\" and ending in \"vs''\", are combined into one. The new chain starts in \"vs\", ends in \"vs''\", and has \"vs'\" in the middle. " >}}
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The proof is very short. We go
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{{< sidenote "right" "concat-note" "by induction on the left evaluation chain" >}}
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It's not a coincidence that defining something like <code>(++)</code>
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(list concatenation) in Haskell typically starts by pattern matching
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on the <em>left</em> list. In fact, proofs by <code>induction</code>
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actually correspond to recursive functions! It's tough putting code blocks
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in sidenotes, but if you're playing with the
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<a href="https://dev.danilafe.com/Web-Projects/blog-static/src/branch/master/code/dawn/DawnEval.v"><code>DawnEval.v</code></a> file, try running
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<code>Print eval_chain_ind</code>, and note the presence of <code>fix</code>,
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the <a href="https://en.wikipedia.org/wiki/Fixed-point_combinator">fixed point
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combinator</a> used to implement recursion.
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{{< /sidenote >}}
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(the one for `e1`). Coq takes care of most of the rest with `auto`.
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The key to this proof is that whatever `P` is contained within a "node"
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in the left chain determines how `eval_step (e_comp e1 e2)` behaves. Whether
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`e1` evaluates to `final` or `middle`, the composition evaluates to `middle`
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(a composition of two expressions cannot be done in one step), so we always
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{{< sidenote "left" "cons-note" "create a new \"cons\" node." >}}
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This is <em>unlike</em> list concatenation, since we typically don't
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create new nodes when appending to an empty list.
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{{< /sidenote >}} via `chain_middle`. Then, the two cases are as follows.
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If the step was `final`, then
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the rest of the steps use only `e2`, and good news, we already have a chain
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for that!
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{{< figure src="coq_eval_chain_base.png" caption="Merging evaluation chains when the first chain only has one step." class="large" alt="A single-step chain connected to another by a line labeled \"chain_middle\"." >}}
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Otherwise, the step was `middle`, an we still have a chain for some
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intermediate program `ei` that starts in some stack `vsi` and ends in `vs'`.
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By induction, we know that _this_ chain can be concatenated with the one
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for `e2`, resulting in a chain for `e_comp ei e2`. All that remains is to
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attach to this sub-chain the one step from `(vs, e1)` to `(vsi, ei)`, which
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is handled by `chain_middle`.
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{{< figure src="coq_eval_chain_inductive.png" caption="Merging evaluation chains when the first chain has a middle step and others." class="large" alt="Visualization of the inductive case of merging chains." >}}
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The `merge` operation is reversible; chains can be split into two pieces,
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one for each composed expression:
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{{< codelines "Coq" "dawn/DawnEval.v" 77 78 >}}
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While interesting, this particular fact isn't used anywhere else in this
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post, and I will omit the proof here.
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#### The Forward Direction
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Let's try rewording our very first proof, `eval_step_correct`, using
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chains. The _direction_ remains the same: given that an expression
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produces a final stack under the formal semantics, we need to
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prove that this expression _evaluates_ to the same final stack using
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a sequence of `eval_step`.
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{{< codelines "Coq" "dawn/DawnEval.v" 93 96 >}}
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The power of this theorem is roughly the same as that of
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the original one: we can use `eval_step_correct` to build up a chain
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by applying it over and over, and we can take the "first element"
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of a chain to serve as a witness for `eval_step_correct`. However,
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the formulation is arguably significantly cleaner, and contains
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a proof for _all_ steps right away, rather than a single one.
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Before we go through the proof, notice that there's actually _two_
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theorems being stated here, which depend on each other. This
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is not surprising given that our semantics are given using two
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data types, `Sem_expr` and `Sem_int`, each of which contains the other.
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Regular proofs by induction, which work on only one of the data types,
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break down because we can't make claims "by induction" about the _other_
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type. For example, while going by induction on `Sem_expr`, we run into
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issues in the `e_int` case while handling \(\text{apply}\). We know
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a single step -- popping the value being run from the stack. But what then?
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The rule for \(\text{apply}\) in `Sem_int` contains another `Sem_expr`
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which confirms that the quoted value properly evaluates. But this other
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`Sem_expr` isn't directly a child of the "bigger" `Sem_expr`, and so we
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don't get an inductive hypothesis about it. We know nothing about it; we're stuck.
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We therefore have two theorems declared together using `with` (just like we
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used `with` to declare `Sem_expr` and `Sem_int`). We have to prove both,
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which is once again a surprisingly easy task thanks to Coq's `auto`. Let's
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start with the first theorem, the one for expression semantics.
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{{< codelines "Coq" "dawn/DawnEval.v" 98 107 >}}
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We go by induction on the semantics data type. There are therefore three cases:
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intrinsics, quotes, and composition. The intrinsic case is handed right
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off to the second theorem (which we'll see momentarily). The quote case
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is very simple since quoted expressions are simply pushed onto the stack in
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a single step (we thus use `chain_final`). Finally, in the composition
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case, we have two sub-proofs, one for each expression being evaluated.
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By induction, we know that each of these sub-proofs can be turned into
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a chain, and we use `eval_chain_merge` to combine these two chains into one.
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That's it.
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|
|
|
Now, let's try the second theorem. The code is even shorter:
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 108 115 >}}
|
|
|
|
The first command, `inversion Hsem`, lets us go case-by-case on the various
|
|
ways an intrinsic can be evaluated. Most intrinsics are quite boring;
|
|
in our evaluator, they only need a single step, and their semantics
|
|
rules guarantee that the stack has the exact kind of data that the evaluator
|
|
expects. We dismiss such cases with `apply chain_final; auto`. The only
|
|
time this doesn't work is when we encounter the \(\text{apply}\) intrinsic;
|
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in that case, however, we can simply use the first theorem we proved.
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|
|
|
#### A Quick Aside: Automation Using `Ltac2`
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|
Going in the other direction will involve lots of situations in which we _know_
|
|
that `eval_step` evaluated to something. Here's a toy proof built around
|
|
one such case:
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 237 246 "hl_lines=5-8">}}
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|
|
|
The proof claims that if the `swap` instruction was evaluated to something,
|
|
then the initial stack must contain two values, and the final stack must
|
|
have those two values on top but flipped. This is very easy to prove, since
|
|
that's the exact behavior of `eval_step` for the `swap` intrinsic. However,
|
|
notice how much boilerplate we're writing: lines 241 through 244 deal entirely
|
|
with ensuring that our stack does, indeed, have two values. This is trivially true:
|
|
if the stack _didn't_ have two values, it wouldn't evaluate to `final`, but to `error`.
|
|
However, it takes some effort to convince Coq of this.
|
|
|
|
This was just for a single intrinsic. What if we're trying to prove something
|
|
for _every_ intrinsic? Things will get messy very quickly. We can't even re-use
|
|
our `destruct vs` code, because different intrinsics need stacks with different numbers
|
|
of values (they have a different _arity_); if we try to handle all cases with at most
|
|
2 values on the stack, we'd have to prove the same thing twice for simpler intrinsics.
|
|
In short, proofs will look like a mess.
|
|
|
|
Things don't have to be this way, though! The boilerplate code is very repetitive, and
|
|
this makes it a good candidate for automation. For this, Coq has `Ltac2`.
|
|
|
|
In short, `Ltac2` is another mini-language contained within Coq. We can use it to put
|
|
into code the decision making that we'd be otherwise doing on our own. For example,
|
|
here's a tactic that checks if the current proof has a hypothesis in which
|
|
an intrinsic is evaluated to something:
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 141 148 >}}
|
|
|
|
`Ltac2` has a pattern matching construct much like Coq itself does, but it can
|
|
pattern match on Coq expressions and proof goals. When pattern matching
|
|
on goals, we use the following notation: `[ h1 : t1, ..., hn : tn |- g ]`, which reads:
|
|
|
|
> Given hypotheses `h1` through `hn`, of types `t1` through `tn` respectively,
|
|
we need to prove `g`.
|
|
|
|
In our pattern match, then, we're ignoring the actual thing we're supposed to prove
|
|
(the tactic we're writing won't be that smart; its user -- ourselves -- will need
|
|
to know when to use it). We are, however, searching for a hypothesis in the form
|
|
`eval_step ?a (e_int ?b) = ?c`. The three variables, `?a`, `?b`, and `?c` are placeholders
|
|
which can be matched with anything. Thus, we expect any hypothesis in which
|
|
an intrinsic is evaluated to anything else (by the way, Coq checks all hypotheses one-by-one,
|
|
starting at the most recent and finishing with the oldest). The code on lines 144 through 146 actually
|
|
performs the `destruct` calls, as well as the `inversion` attempts that complete
|
|
any proofs with an inconsistent assumption (like `err = final vs'`).
|
|
|
|
So how do these lines work? Well, first we need to get a handle on the hypothesis we found.
|
|
Various tactics can manipulate the proof state, and cause hypotheses to disappear;
|
|
by calling `Control.hyp` on `h`, we secure a more permanent hold on our evaluation assumption.
|
|
In the next line, we call _another_ `Ltac2` function, `destruct_int_stack`, which unpacks
|
|
the stack exactly as many times as necessary. We'll look at this function in a moment.
|
|
Finally, we use regular old tactics. Specifically, we use `inversion` (as mentioned before).
|
|
I use `fail` after `inversion` to avoid cluttering the proof in case there's _not_
|
|
a contradiction.
|
|
|
|
On to `destruct_int_stack`. The definition is very simple:
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 139 139 >}}
|
|
|
|
The main novelty is that this function takes two arguments, both of which are Coq expressions:
|
|
`int`, or the intrinsic being evaluated, and `va`, the stack that's being analyzed. The `constr`
|
|
type in Coq holds terms. Let's look at `int_arity` next:
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 128 137 >}}
|
|
|
|
This is a pretty standard pattern match that assigns to each expression its arity. However, we're
|
|
case analyzing over _literally any possible Coq expression_, so we need to handle the case in which
|
|
the expression isn't actually a specific intrinsic. For this, we use `Control.throw` with
|
|
the `Not_intrinsic` exception.
|
|
|
|
Wait a moment, does Coq just happen to include a `Not_intrinsic` exception? No, it does not.
|
|
We have to register that one ourselves. In `Ltac2`, the type of exception (`exn`) is _extensible_,
|
|
which means we can add on to it. We add just a single constructor with no arguments:
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 118 118 >}}
|
|
|
|
Finally, unpacking the value stack. Here's the code for that:
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 120 126 >}}
|
|
|
|
This function accepts the arity of an operation, and unpacks the stack that many times.
|
|
`Ltac2` doesn't have a way to pattern match on numbers, so we resort to good old "less than or equal",
|
|
and and `if`/`else`. If the arity is zero (or less than zero, since it's an integer), we don't
|
|
need to unpack anymore. This is our base case. Otherwise, we generate two new free variables
|
|
(we can't just hardcode `v1` and `v2`, since they may be in use elsewhere in the proof). To this
|
|
end we use `Fresh.in_goal` and give it a "base symbol" to build on. We then use
|
|
`destruct`, passing it our "scrutinee" (the expression being destructed) and the names
|
|
we generated for its components. This generates multiple goals; the `Control.enter` tactic
|
|
is used to run code for each one of these goals. In the non-empty list case, we try to break
|
|
apart its tail as necessary by recursively calling `destruct_n`.
|
|
|
|
That's pretty much it! We can now use our tactic from Coq like any other. Rewriting
|
|
our earlier proof about \(\text{swap}\), we now only need to handle the valid case:
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 248 254 >}}
|
|
|
|
We'll be using this new `ensure_valid_stack` tactic in our subsequent proofs.
|
|
|
|
#### The Backward Direction
|
|
After our last proof before the `Ltac2` diversion, we know that our evaluator matches our semantics, but only when a `Sem_expr`
|
|
object exists for our program. However, invalid programs don't have a `Sem_expr` object
|
|
(there's no way to prove that they evaluate to anything). Does our evaluator behave
|
|
properly on "bad" programs, too? We've not ruled out that our evaluator produces junk
|
|
`final` or `middle` outputs whenever it encounters an error. We need another theorem:
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 215 216 >}}
|
|
|
|
That is, if our evalutor reaches a final state, this state matches our semantics.
|
|
This proof is most conveniently split into two pieces. The first piece says that
|
|
if our evaluator completes in a single step, then this step matches our semantics.
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 158 175 >}}
|
|
|
|
The statement for a non-`final` step is more involved; the one step by itself need
|
|
not match the semantics, since it only carries out a part of a computation. However,
|
|
we _can_ say that if the "rest of the program" matches the semantics, then so does
|
|
the whole expression.
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 177 213 >}}
|
|
|
|
Finally, we snap these two pieces together in `eval_step_sem_back`:
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 215 222 >}}
|
|
|
|
We have now proved complete equivalence: our evaluator completes in a final state
|
|
if and only if our semantics lead to this same final state. As a corollary of this,
|
|
we can see that if a program is invalid (it doesn't evaluate to anything under our semantics),
|
|
then our evaluator won't finish in a `final` state:
|
|
|
|
{{< codelines "Coq" "dawn/DawnEval.v" 224 229 >}}
|
|
|
|
### Making a Mini-REPL
|
|
We can now be pretty confident about our evaluator. However, this whole business with using GHCi
|
|
to run our programs is rather inconvenient; I'd rather write `[drop]` than `E_quote (E_int Drop)`.
|
|
I'd also rather _read_ the former instead of the latter. We can do some work in Haskell to make
|
|
playing with our interpreter more convenient.
|
|
|
|
#### Pretty Printing Code
|
|
Coq generated Haskell data types that correspond precisely to the data types we defined for our
|
|
proofs. We can use the standard type class mechanism in Haskell to define how they should be
|
|
printed:
|
|
|
|
{{< codelines "Haskell" "dawn/Ucc.hs" 8 22 >}}
|
|
|
|
Now our expressions and values print a lot nicer:
|
|
|
|
```
|
|
ghci> true
|
|
[swap drop]
|
|
ghci> false
|
|
[drop]
|
|
ghci> UccGen.or
|
|
clone apply
|
|
```
|
|
|
|
#### Reading Code In
|
|
The Parsec library in Haskell can be used to convert text back into data structures.
|
|
It's not too hard to create a parser for UCC:
|
|
|
|
{{< codelines "Haskell" "dawn/Ucc.hs" 24 44 >}}
|
|
|
|
Now, `parseExpression` can be used to read code:
|
|
|
|
```
|
|
ghci> parseExpression "[drop] [drop]"
|
|
Right [drop] [drop]
|
|
```
|
|
|
|
#### The REPL
|
|
We now literally have the three pieces of a read-evaluate-print loop. All that's left
|
|
is putting them together:
|
|
|
|
{{< codelines "Haskell" "dawn/Ucc.hs" 53 64 >}}
|
|
|
|
We now have our own little verified evaluator:
|
|
|
|
```
|
|
$ ghci Ucc
|
|
$ ghc -main-is Ucc Ucc
|
|
$ ./Ucc
|
|
> [drop] [drop] clone apply
|
|
[[drop]]
|
|
> [drop] [swap drop] clone apply
|
|
[[swap drop]]
|
|
> [swap drop] [drop] clone apply
|
|
[[swap drop]]
|
|
> [swap drop] [swap drop] clone apply
|
|
[[swap drop]]
|
|
```
|
|
|
|
### Potential Future Work
|
|
We now have a verified UCC evaluator in Haskell. What next?
|
|
|
|
1. We only verified the evaluation component of our REPL. In fact,
|
|
the whole thing is technically a bit buggy due to the parser:
|
|
```
|
|
> [drop] drop coq is a weird name to say out loud in interviews
|
|
[]
|
|
```
|
|
Shouldn't this be an error? Do you see why it's not? There's work in
|
|
writing formally verified parsers; some time ago I saw a Galois
|
|
talk about a [formally verified parser generator](https://galois.com/blog/2019/09/tech-talk-a-verified-ll1-parser-generator/).
|
|
We could use this formally verified parser generator to create our parsers, and then be
|
|
sure that our grammar is precisely followed.
|
|
2. We could try make our evaluator a bit smarter. One thing we could definitely do
|
|
is maker our REPL support variables. Then, we would be able to write:
|
|
```
|
|
> true = [swap drop]
|
|
> false = [drop]
|
|
> or = clone apply
|
|
> true false or
|
|
[swap drop]
|
|
```
|
|
There are different ways to go about this. One way is to extend our `expr` data type
|
|
with a variable constructor. This would complicate the semantics (a _lot_), but it would
|
|
allow us to prove facts about variables. Alternatively, we could implement expressions
|
|
as syntax sugar in our parser. Using a variable would be the same as simply
|
|
pasting in the variable's definition. This is pretty much what the Dawn article
|
|
seems to be doing.
|
|
3. We could prove more things. Can we confirm, once and for all, the correctness of \(\text{quote}_n\),
|
|
for _any_ \(n\)? Is there is a generalized way of converting inductive data types into a UCC encoding?
|
|
Or could we perhaps formally verify the following comment from Lobsters:
|
|
|
|
> with the encoding of natural numbers given, n+1 contains the definition of n duplicated two times.
|
|
This means that the encoding of n has size exponential in n, which seems extremely impractical.
|
|
|
|
The world's our oyster!
|
|
|
|
Despite all of these exciting possibilities, this is where I stop, for now. I hope you enjoyed this article,
|
|
and thank you for reading!
|