(* Title: HOL/Isar_examples/ExprCompiler.thy
ID: $Id$
Author: Markus Wenzel, TU Muenchen
Correctness of a simple expression/stack-machine compiler.
*)
header {* Correctness of a simple expression compiler *}
theory ExprCompiler = Main:
text {*
This is a (rather trivial) example of program verification. We model
a compiler for translating expressions to stack machine instructions,
and prove its correctness wrt.\ some evaluation semantics.
*}
subsection {* Binary operations *}
text {*
Binary operations are just functions over some type of values. This
is both for abstract syntax and semantics, i.e.\ we use a ``shallow
embedding'' here.
*}
types
'val binop = "'val => 'val => 'val"
subsection {* Expressions *}
text {*
The language of expressions is defined as an inductive type,
consisting of variables, constants, and binary operations on
expressions.
*}
datatype ('adr, 'val) expr =
Variable 'adr |
Constant 'val |
Binop "'val binop" "('adr, 'val) expr" "('adr, 'val) expr"
text {*
Evaluation (wrt.\ some environment of variable assignments) is
defined by primitive recursion over the structure of expressions.
*}
consts
eval :: "('adr, 'val) expr => ('adr => 'val) => 'val"
primrec
"eval (Variable x) env = env x"
"eval (Constant c) env = c"
"eval (Binop f e1 e2) env = f (eval e1 env) (eval e2 env)"
subsection {* Machine *}
text {*
Next we model a simple stack machine, with three instructions.
*}
datatype ('adr, 'val) instr =
Const 'val |
Load 'adr |
Apply "'val binop"
text {*
Execution of a list of stack machine instructions is easily defined
as follows.
*}
consts
exec :: "(('adr, 'val) instr) list
=> 'val list => ('adr => 'val) => 'val list"
primrec
"exec [] stack env = stack"
"exec (instr # instrs) stack env =
(case instr of
Const c => exec instrs (c # stack) env
| Load x => exec instrs (env x # stack) env
| Apply f => exec instrs (f (hd stack) (hd (tl stack))
# (tl (tl stack))) env)"
constdefs
execute :: "(('adr, 'val) instr) list => ('adr => 'val) => 'val"
"execute instrs env == hd (exec instrs [] env)"
subsection {* Compiler *}
text {*
We are ready to define the compilation function of expressions to
lists of stack machine instructions.
*}
consts
compile :: "('adr, 'val) expr => (('adr, 'val) instr) list"
primrec
"compile (Variable x) = [Load x]"
"compile (Constant c) = [Const c]"
"compile (Binop f e1 e2) = compile e2 @ compile e1 @ [Apply f]"
text {*
The main result of this development is the correctness theorem for
$\idt{compile}$. We first establish a lemma about $\idt{exec}$ and
list append.
*}
lemma exec_append:
"ALL stack. exec (xs @ ys) stack env =
exec ys (exec xs stack env) env" (is "?P xs")
proof (induct xs)
show "?P []" by simp
next
fix x xs assume hyp: "?P xs"
show "?P (x # xs)"
proof (induct x)
from hyp show "!!val. ?P (Const val # xs)" by simp
from hyp show "!!adr. ?P (Load adr # xs)" by simp
from hyp show "!!fun. ?P (Apply fun # xs)" by simp
qed
qed
theorem correctness: "execute (compile e) env = eval e env"
proof -
have "ALL stack. exec (compile e) stack env =
eval e env # stack" (is "?P e")
proof (induct e)
show "!!adr. ?P (Variable adr)" by simp
show "!!val. ?P (Constant val)" by simp
show "!!fun e1 e2. ?P e1 ==> ?P e2 ==> ?P (Binop fun e1 e2)"
by (simp add: exec_append)
qed
thus ?thesis by (simp add: execute_def)
qed
text {*
\bigskip In the proofs above, the \name{simp} method does quite a lot
of work behind the scenes (mostly ``functional program execution'').
Subsequently, the same reasoning is elaborated in detail --- at most
one recursive function definition is used at a time. Thus we get a
better idea of what is actually going on.
*}
lemma exec_append':
"ALL stack. exec (xs @ ys) stack env
= exec ys (exec xs stack env) env" (is "?P xs")
proof (induct xs)
show "?P []" (is "ALL s. ?Q s")
proof
fix s have "exec ([] @ ys) s env = exec ys s env" by simp
also have "... = exec ys (exec [] s env) env" by simp
finally show "?Q s" .
qed
fix x xs assume hyp: "?P xs"
show "?P (x # xs)"
proof (induct x)
fix val
show "?P (Const val # xs)" (is "ALL s. ?Q s")
proof
fix s
have "exec ((Const val # xs) @ ys) s env =
exec (Const val # xs @ ys) s env"
by simp
also have "... = exec (xs @ ys) (val # s) env" by simp
also from hyp
have "... = exec ys (exec xs (val # s) env) env" ..
also have "... = exec ys (exec (Const val # xs) s env) env"
by simp
finally show "?Q s" .
qed
next
fix adr from hyp show "?P (Load adr # xs)" by simp -- {* same as above *}
next
fix fun
show "?P (Apply fun # xs)" (is "ALL s. ?Q s")
proof
fix s
have "exec ((Apply fun # xs) @ ys) s env =
exec (Apply fun # xs @ ys) s env"
by simp
also have "... =
exec (xs @ ys) (fun (hd s) (hd (tl s)) # (tl (tl s))) env"
by simp
also from hyp have "... =
exec ys (exec xs (fun (hd s) (hd (tl s)) # tl (tl s)) env) env"
..
also have "... = exec ys (exec (Apply fun # xs) s env) env" by simp
finally show "?Q s" .
qed
qed
qed
theorem correctness: "execute (compile e) env = eval e env"
proof -
have exec_compile:
"ALL stack. exec (compile e) stack env = eval e env # stack"
(is "?P e")
proof (induct e)
fix adr show "?P (Variable adr)" (is "ALL s. ?Q s")
proof
fix s
have "exec (compile (Variable adr)) s env = exec [Load adr] s env"
by simp
also have "... = env adr # s" by simp
also have "env adr = eval (Variable adr) env" by simp
finally show "?Q s" .
qed
next
fix val show "?P (Constant val)" by simp -- {* same as above *}
next
fix fun e1 e2 assume hyp1: "?P e1" and hyp2: "?P e2"
show "?P (Binop fun e1 e2)" (is "ALL s. ?Q s")
proof
fix s have "exec (compile (Binop fun e1 e2)) s env
= exec (compile e2 @ compile e1 @ [Apply fun]) s env" by simp
also have "... = exec [Apply fun]
(exec (compile e1) (exec (compile e2) s env) env) env"
by (simp only: exec_append)
also from hyp2
have "exec (compile e2) s env = eval e2 env # s" ..
also from hyp1
have "exec (compile e1) ... env = eval e1 env # ..." ..
also have "exec [Apply fun] ... env =
fun (hd ...) (hd (tl ...)) # (tl (tl ...))" by simp
also have "... = fun (eval e1 env) (eval e2 env) # s" by simp
also have "fun (eval e1 env) (eval e2 env) =
eval (Binop fun e1 e2) env"
by simp
finally show "?Q s" .
qed
qed
have "execute (compile e) env = hd (exec (compile e) [] env)"
by (simp add: execute_def)
also from exec_compile
have "exec (compile e) [] env = [eval e env]" ..
also have "hd ... = eval e env" by simp
finally show ?thesis .
qed
end