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Commenting BasicSyntax
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* License: https://creativecommons.org/licenses/by-nc-nd/4.0/ *)
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Require Import Frap.
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(* This [Import] command is for including a library of code, theorems, tactics, etc.
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* Here we just including the standard library of the book.
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* We won't distinguish carefully between built-in Coq features and those provided by that library. *)
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(* As a first example, let's look at the syntax of simple arithmetic expressions.
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* We use the Coq feature of modules, which let us group related definitions together.
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* A key benefit is that names can be reused across modules,
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* which is helpful to define several variants of a suite of functionality,
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* within a single source file. *)
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Module ArithWithConstants.
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(* The following definition closely mirrors a standard BNF grammar for expressions.
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* It defines abstract syntax trees of arithmetic expressions. *)
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Inductive arith : Set :=
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| Const (n : nat)
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| Plus (e1 e2 : arith)
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| Times (e1 e2 : arith).
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(* Here are a few examples of specific expressions. *)
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Example ex1 := Const 42.
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Example ex2 := Plus (Const 1) (Times (Const 2) (Const 3)).
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(* How many nodes appear in the tree for an expression?
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* Unlike in many programming languages, in Coq,
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* recursive functions must be marked as recursive explicitly.
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* That marking comes with the [Fixpoint] command,
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* as opposed to [Definition].
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* Note also that Coq checks termination of each recursive definition.
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* Intuitively, recursive calls must be on subterms of the original argument. *)
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Fixpoint size (e : arith) : nat :=
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match e with
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| Const _ => 1
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@ -23,9 +40,11 @@ Module ArithWithConstants.
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| Times e1 e2 => 1 + size e1 + size e2
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end.
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(* Here's how to run a program (evaluate a term) in Coq. *)
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Compute size ex1.
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Compute size ex2.
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(* What's the longest path from the root of a syntax tree to a leaf? *)
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Fixpoint depth (e : arith) : nat :=
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match e with
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| Const _ => 1
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Compute depth ex1.
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Compute size ex2.
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(* Our first proof!
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* Size is an upper bound on depth. *)
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Theorem depth_le_size : forall e, depth e <= size e.
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Proof.
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(* Within a proof, we apply commands called *tactics*.
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* Here's our first one.
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* Throughout the book's Coq code, we give a brief note documenting each tactic,
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* after its first use.
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* Keep in mind that the best way to understand what's going on
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* is to run the proof script for yourself, inspecting intermediate states! *)
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induct e.
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(* [induct x]: where [x] is a variable in the theorem statement,
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* structure the proof by induction on the structure of [x].
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* You will get one generated subgoal per constructor in the
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* inductive definition of [x]. (Indeed, it is required that
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* [x]'s type was introduced with [Inductive].) *)
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simplify.
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(* [simplify]: simplify throughout the goal, applying the definitions of
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* recursive functions directly. That is, when a subterm
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* matches one of the [match] cases in a defining [Fixpoint],
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* replace with the body of that case, then repeat. *)
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linear_arithmetic.
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(* [linear_arithemtic]: a complete decision procedure for linear arithmetic.
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* Relevant formulas are essentially those built up from
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* variables and constant natural numbers and integers
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* using only addition, with equality and inequality
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* comparisons on top. (Multiplication by constants
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* is supported, as a shorthand for repeated addition.) *)
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simplify.
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linear_arithmetic.
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Theorem depth_le_size_snazzy : forall e, depth e <= size e.
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Proof.
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induct e; simplify; linear_arithmetic.
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(* Oo, look at that! Chaining tactics with semicolon, as in [t1; t2],
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* asks to run [t1] on the goal, then run [t2] on *every*
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* generated subgoal. This is an essential ingredient for automation. *)
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Qed.
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(* A silly recursive function: swap the operand orders of all binary operators. *)
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Fixpoint commuter (e : arith) : arith :=
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match e with
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| Const _ => e
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Compute commuter ex1.
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Compute commuter ex2.
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(* [commuter] has all the appropriate interactions with other functions (and itself). *)
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Theorem size_commuter : forall e, size (commuter e) = size e.
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Proof.
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induct e; simplify; linear_arithmetic.
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Theorem commuter_inverse : forall e, commuter (commuter e) = e.
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Proof.
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induct e; simplify; equality.
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(* [equality]: a complete decision procedure for the theory of equality
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* and uninterpreted functions. That is, the goal must follow
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* from only reflexivity, symmetry, transitivity, and congruence
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* of equality, including that functions really do behave as functions. *)
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Qed.
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End ArithWithConstants.
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(* Let's shake things up a bit by adding variables to expressions.
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* Note that all of the automated proof scripts from before will keep working
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* with no changes! That sort of "free" proof evolution is invaluable for
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* theorems about real-world compilers, say. *)
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Module ArithWithVariables.
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Inductive arith : Set :=
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| Const (n : nat)
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| Var (x : var)
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| Var (x : var) (* <-- this is the new constructor! *)
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| Plus (e1 e2 : arith)
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| Times (e1 e2 : arith).
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induct e; simplify; equality.
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Qed.
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(* Now that we have variables, we can consider new operations,
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* like substituting an expression for a variable.
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* We use an infix operator [==v] for equality tests on strings.
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* It has a somewhat funny and very expressive type,
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* whose details we will try to gloss over.
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* (To dig into it more on your own, the appropriate keyword is "dependent types.") *)
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Fixpoint substitute (inThis : arith) (replaceThis : var) (withThis : arith) : arith :=
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match inThis with
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| Const _ => inThis
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| Times e1 e2 => Times (substitute e1 replaceThis withThis) (substitute e2 replaceThis withThis)
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end.
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(* An intuitive property about how much [substitute] might increase depth. *)
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Theorem substitute_depth : forall replaceThis withThis inThis,
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depth (substitute inThis replaceThis withThis) <= depth inThis + depth withThis.
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Proof.
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simplify.
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cases (x ==v replaceThis).
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(* [cases e]: break the proof into one case for each constructor that might have
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* been used to build the value of expression [e]. In the special case where
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* [e] essentially has a Boolean type, we consider whether [e] is true or false. *)
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linear_arithmetic.
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simplify.
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linear_arithmetic.
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linear_arithmetic.
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Qed.
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(* Let's get fancier about automation, using [match goal] to pattern-match the goal
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* and decide what to do next!
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* The [|-] syntax separates hypotheses and conclusion in a goal.
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* The [context] syntax is for matching against *any subterm* of a term.
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* The construct [try] is also useful, for attempting a tactic and rolling back
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* the effect if any error is encountered. *)
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Theorem substitute_depth_snazzy : forall replaceThis withThis inThis,
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depth (substitute inThis replaceThis withThis) <= depth inThis + depth withThis.
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Proof.
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end; linear_arithmetic.
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Qed.
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(* A silly self-substitution has no effect. *)
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Theorem substitute_self : forall replaceThis inThis,
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substitute inThis replaceThis (Var replaceThis) = inThis.
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Proof.
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