header {*
Separation logic for Turing Machines
*}
theory Hoare_tm
imports Hoare_gen My_block Data_slot
begin
ML {*
fun pretty_terms ctxt trms =
Pretty.block (Pretty.commas (map (Syntax.pretty_term ctxt) trms))
*}
ML {*
structure StepRules = Named_Thms
(val name = @{binding "step"}
val description = "Theorems for hoare rules for every step")
*}
ML {*
structure FwdRules = Named_Thms
(val name = @{binding "fwd"}
val description = "Theorems for fwd derivation of seperation implication")
*}
setup {* StepRules.setup *}
setup {* FwdRules.setup *}
method_setup prune =
{* Scan.succeed (SIMPLE_METHOD' o (K (K prune_params_tac))) *}
"pruning parameters"
lemma int_add_C:
"x + (y::int) = y + x"
by simp
lemma int_add_A : "(x + y) + z = x + (y + (z::int))"
by simp
lemma int_add_LC: "x + (y + (z::int)) = y + (x + z)"
by simp
lemmas int_add_ac = int_add_A int_add_C int_add_LC
section {* Operational Semantics of TM *}
datatype taction = W0 | W1 | L | R
type_synonym tstate = nat
datatype Block = Oc | Bk
(* the successor state when tape symbol is Bk or Oc, respectively *)
type_synonym tm_inst = "(taction \<times> tstate) \<times> (taction \<times> tstate)"
(* - number of faults (nat)
- TM program (nat \<rightharpoonup> tm_inst)
- current state (nat)
- position of head (int)
- tape (int \<rightharpoonup> Block)
*)
type_synonym tconf = "nat \<times> (nat \<rightharpoonup> tm_inst) \<times> nat \<times> int \<times> (int \<rightharpoonup> Block)"
(* updates the position/tape according to an action *)
fun
next_tape :: "taction \<Rightarrow> (int \<times> (int \<rightharpoonup> Block)) \<Rightarrow> (int \<times> (int \<rightharpoonup> Block))"
where
"next_tape W0 (pos, m) = (pos, m(pos \<mapsto> Bk))" |
"next_tape W1 (pos, m) = (pos, m(pos \<mapsto> Oc))" |
"next_tape L (pos, m) = (pos - 1, m)" |
"next_tape R (pos, m) = (pos + 1, m)"
fun tstep :: "tconf \<Rightarrow> tconf"
where "tstep (faults, prog, pc, pos, m) =
(case (prog pc) of
Some ((action0, pc0), (action1, pc1)) \<Rightarrow>
case (m pos) of
Some Bk \<Rightarrow> (faults, prog, pc0, next_tape action0 (pos, m)) |
Some Oc \<Rightarrow> (faults, prog, pc1, next_tape action1 (pos, m)) |
None \<Rightarrow> (faults + 1, prog, pc, pos, m)
| None \<Rightarrow> (faults + 1, prog, pc, pos, m))"
lemma tstep_splits:
"(P (tstep s)) = ((\<forall> faults prog pc pos m action0 pc0 action1 pc1.
s = (faults, prog, pc, pos, m) \<longrightarrow>
prog pc = Some ((action0, pc0), (action1, pc1)) \<longrightarrow>
m pos = Some Bk \<longrightarrow> P (faults, prog, pc0, next_tape action0 (pos, m))) \<and>
(\<forall> faults prog pc pos m action0 pc0 action1 pc1.
s = (faults, prog, pc, pos, m) \<longrightarrow>
prog pc = Some ((action0, pc0), (action1, pc1)) \<longrightarrow>
m pos = Some Oc \<longrightarrow> P (faults, prog, pc1, next_tape action1 (pos, m))) \<and>
(\<forall> faults prog pc pos m action0 pc0 action1 pc1.
s = (faults, prog, pc, pos, m) \<longrightarrow>
prog pc = Some ((action0, pc0), (action1, pc1)) \<longrightarrow>
m pos = None \<longrightarrow> P (faults + 1, prog, pc, pos, m)) \<and>
(\<forall> faults prog pc pos m .
s = (faults, prog, pc, pos, m) \<longrightarrow>
prog pc = None \<longrightarrow> P (faults + 1, prog, pc, pos, m))
)"
by (cases s) (auto split: option.splits Block.splits)
datatype tresource =
TM int Block (* at the position int of the tape is a Bl or Oc *)
| TC nat tm_inst (* at the address nat is a certain instruction *)
| TAt nat (* TM is at state nat*)
| TPos int (* head of TM is at position int *)
| TFaults nat (* there are nat faults *)
definition "tprog_set prog = {TC i inst | i inst. prog i = Some inst}"
definition "tpc_set pc = {TAt pc}"
definition "tmem_set m = {TM i n | i n. m (i) = Some n}"
definition "tpos_set pos = {TPos pos}"
definition "tfaults_set faults = {TFaults faults}"
lemmas tpn_set_def = tprog_set_def tpc_set_def tmem_set_def tfaults_set_def tpos_set_def
fun trset_of :: "tconf \<Rightarrow> tresource set"
where "trset_of (faults, prog, pc, pos, m) =
tprog_set prog \<union> tpc_set pc \<union> tpos_set pos \<union> tmem_set m \<union> tfaults_set faults"
interpretation tm: sep_exec tstep trset_of .
section {* Assembly language for TMs and its program logic *}
subsection {* The assembly language *}
datatype tpg =
TInstr tm_inst
| TLabel nat
| TSeq tpg tpg
| TLocal "nat \<Rightarrow> tpg"
notation TLocal (binder "TL " 10)
abbreviation
tprog_instr :: "tm_inst \<Rightarrow> tpg" ("\<guillemotright> _" [61] 61)
where "\<guillemotright> i \<equiv> TInstr i"
abbreviation tprog_seq ::
"tpg \<Rightarrow> tpg \<Rightarrow> tpg" (infixr ";" 52)
where "c1 ; c2 \<equiv> TSeq c1 c2"
definition "sg e = (\<lambda>s. s = e)"
type_synonym tassert = "tresource set \<Rightarrow> bool"
abbreviation
t_hoare :: "tassert \<Rightarrow> tassert \<Rightarrow> tassert \<Rightarrow> bool" ("(\<lbrace>(1_)\<rbrace>/ (_)/ \<lbrace>(1_)\<rbrace>)" 50)
where
"\<lbrace>p\<rbrace> c \<lbrace>q\<rbrace> == sep_exec.Hoare_gen tstep trset_of p c q"
abbreviation it_hoare ::
"('a::sep_algebra \<Rightarrow> tresource set \<Rightarrow> bool) \<Rightarrow> ('a \<Rightarrow> bool) \<Rightarrow> (tresource set \<Rightarrow> bool) \<Rightarrow> ('a \<Rightarrow> bool) \<Rightarrow> bool"
("(1_).(\<lbrace>(1_)\<rbrace>/ (_)/ \<lbrace>(1_)\<rbrace>)" 50)
where "I. \<lbrace>P\<rbrace> c \<lbrace>Q\<rbrace> == sep_exec.IHoare tstep trset_of I P c Q"
(*
primrec tpg_len :: "tpg \<Rightarrow> nat" where
"tpg_len (TInstr ai) = 1" |
"tpg_len (TSeq p1 p2) = tpg_len p1 + tpg_len " |
"tpg_len (TLocal fp) = tpg_len (fp 0)" |
"tpg_len (TLabel l) = 0"
*)
primrec tassemble_to :: "tpg \<Rightarrow> nat \<Rightarrow> nat \<Rightarrow> tassert"
where
"tassemble_to (TInstr ai) i j = (sg ({TC i ai}) ** <(j = i + 1)>)" |
"tassemble_to (TSeq p1 p2) i j = (EXS j'. (tassemble_to p1 i j') ** (tassemble_to p2 j' j))" |
"tassemble_to (TLocal fp) i j = (EXS l. (tassemble_to (fp l) i j))" |
"tassemble_to (TLabel l) i j = <(i = j \<and> j = l)>"
declare tassemble_to.simps [simp del]
lemmas tasmp = tassemble_to.simps (2, 3, 4)
abbreviation
tasmb_to :: "nat \<Rightarrow> tpg \<Rightarrow> nat \<Rightarrow> tassert" ("_ :[ _ ]: _" [60, 60, 60] 60)
where
"i :[ tpg ]: j \<equiv> tassemble_to tpg i j"
lemma EXS_intro:
assumes h: "(P x) s"
shows "(EXS x. P(x)) s"
by (smt h pred_ex_def sep_conj_impl)
lemma EXS_elim:
assumes "(EXS x. P x) s"
obtains x where "P x s"
by (metis assms pred_ex_def)
lemma EXS_eq:
fixes x
assumes h: "Q (p x)"
and h1: "\<And> y s. \<lbrakk>p y s\<rbrakk> \<Longrightarrow> y = x"
shows "p x = (EXS x. p x)"
proof
fix s
show "p x s = (EXS x. p x) s"
proof
assume "p x s"
thus "(EXS x. p x) s" by (auto simp:pred_ex_def)
next
assume "(EXS x. p x) s"
thus "p x s"
proof(rule EXS_elim)
fix y
assume "p y s"
from this[unfolded h1[OF this]] show "p x s" .
qed
qed
qed
definition "tpg_fold tpgs = foldr TSeq (butlast tpgs) (last tpgs)"
lemma tpg_fold_sg:
"tpg_fold [tpg] = tpg"
by (simp add:tpg_fold_def)
lemma tpg_fold_cons:
assumes h: "tpgs \<noteq> []"
shows "tpg_fold (tpg#tpgs) = (tpg; (tpg_fold tpgs))"
using h
proof(induct tpgs arbitrary:tpg)
case (Cons tpg1 tpgs1)
thus ?case
proof(cases "tpgs1 = []")
case True
thus ?thesis by (simp add:tpg_fold_def)
next
case False
show ?thesis
proof -
have eq_1: "butlast (tpg # tpg1 # tpgs1) = tpg # (butlast (tpg1 # tpgs1))"
by simp
from False have eq_2: "last (tpg # tpg1 # tpgs1) = last (tpg1 # tpgs1)"
by simp
have eq_3: "foldr (op ;) (tpg # butlast (tpg1 # tpgs1)) (last (tpg1 # tpgs1)) =
(tpg ; (foldr (op ;) (butlast (tpg1 # tpgs1)) (last (tpg1 # tpgs1))))"
by simp
show ?thesis
apply (subst (1) tpg_fold_def, unfold eq_1 eq_2 eq_3)
by (fold tpg_fold_def, simp)
qed
qed
qed auto
lemmas tpg_fold_simps = tpg_fold_sg tpg_fold_cons
lemma tpg_fold_app:
assumes h1: "tpgs1 \<noteq> []"
and h2: "tpgs2 \<noteq> []"
shows "i:[(tpg_fold (tpgs1 @ tpgs2))]:j = i:[(tpg_fold (tpgs1); tpg_fold tpgs2)]:j"
using h1 h2
proof(induct tpgs1 arbitrary: i j tpgs2)
case (Cons tpg1' tpgs1')
thus ?case (is "?L = ?R")
proof(cases "tpgs1' = []")
case False
from h2 have "(tpgs1' @ tpgs2) \<noteq> []"
by (metis Cons.prems(2) Nil_is_append_conv)
have "?L = (i :[ tpg_fold (tpg1' # (tpgs1' @ tpgs2)) ]: j )" by simp
also have "\<dots> = (i:[(tpg1'; (tpg_fold (tpgs1' @ tpgs2)))]:j )"
by (simp add:tpg_fold_cons[OF `(tpgs1' @ tpgs2) \<noteq> []`])
also have "\<dots> = ?R"
proof -
have "(EXS j'. i :[ tpg1' ]: j' \<and>* j' :[ tpg_fold (tpgs1' @ tpgs2) ]: j) =
(EXS j'. (EXS j'a. i :[ tpg1' ]: j'a \<and>* j'a :[ tpg_fold tpgs1' ]: j') \<and>*
j' :[ tpg_fold tpgs2 ]: j)"
proof(default+)
fix s
assume "(EXS j'. i :[ tpg1' ]: j' \<and>* j' :[ tpg_fold (tpgs1' @ tpgs2) ]: j) s"
thus "(EXS j'. (EXS j'a. i :[ tpg1' ]: j'a \<and>* j'a :[ tpg_fold tpgs1' ]: j') \<and>*
j' :[ tpg_fold tpgs2 ]: j) s"
proof(elim EXS_elim)
fix j'
assume "(i :[ tpg1' ]: j' \<and>* j' :[ tpg_fold (tpgs1' @ tpgs2) ]: j) s"
from this[unfolded Cons(1)[OF False Cons(3)] tassemble_to.simps]
show "(EXS j'. (EXS j'a. i :[ tpg1' ]: j'a \<and>* j'a :[ tpg_fold tpgs1' ]: j') \<and>*
j' :[ tpg_fold tpgs2 ]: j) s"
proof(elim sep_conjE EXS_elim)
fix x y j'a xa ya
assume h: "(i :[ tpg1' ]: j') x"
"x ## y" "s = x + y"
"(j' :[ tpg_fold tpgs1' ]: j'a) xa"
"(j'a :[ tpg_fold tpgs2 ]: j) ya"
" xa ## ya" "y = xa + ya"
show "(EXS j'. (EXS j'a. i :[ tpg1' ]: j'a \<and>*
j'a :[ tpg_fold tpgs1' ]: j') \<and>* j' :[ tpg_fold tpgs2 ]: j) s"
(is "(EXS j'. (?P j' \<and>* ?Q j')) s")
proof(rule EXS_intro[where x = "j'a"])
from `(j'a :[ tpg_fold tpgs2 ]: j) ya` have "(?Q j'a) ya" .
moreover have "(?P j'a) (x + xa)"
proof(rule EXS_intro[where x = j'])
have "x + xa = x + xa" by simp
moreover from `x ## y` `y = xa + ya` `xa ## ya`
have "x ## xa" by (metis sep_disj_addD)
moreover note `(i :[ tpg1' ]: j') x` `(j' :[ tpg_fold tpgs1' ]: j'a) xa`
ultimately show "(i :[ tpg1' ]: j' \<and>* j' :[ tpg_fold tpgs1' ]: j'a) (x + xa)"
by (auto intro!:sep_conjI)
qed
moreover from `x##y` `y = xa + ya` `xa ## ya`
have "(x + xa) ## ya"
by (metis sep_disj_addI1 sep_disj_commuteI)
moreover from `s = x + y` `y = xa + ya`
have "s = (x + xa) + ya"
by (metis h(2) h(6) sep_add_assoc sep_disj_addD1 sep_disj_addD2)
ultimately show "(?P j'a \<and>* ?Q j'a) s"
by (auto intro!:sep_conjI)
qed
qed
qed
next
fix s
assume "(EXS j'. (EXS j'a. i :[ tpg1' ]: j'a \<and>* j'a :[ tpg_fold tpgs1' ]: j') \<and>*
j' :[ tpg_fold tpgs2 ]: j) s"
thus "(EXS j'. i :[ tpg1' ]: j' \<and>* j' :[ tpg_fold (tpgs1' @ tpgs2) ]: j) s"
proof(elim EXS_elim sep_conjE)
fix j' x y j'a xa ya
assume h: "(j' :[ tpg_fold tpgs2 ]: j) y"
"x ## y" "s = x + y" "(i :[ tpg1' ]: j'a) xa"
"(j'a :[ tpg_fold tpgs1' ]: j') ya" "xa ## ya" "x = xa + ya"
show "(EXS j'. i :[ tpg1' ]: j' \<and>* j' :[ tpg_fold (tpgs1' @ tpgs2) ]: j) s"
proof(rule EXS_intro[where x = j'a])
from `(i :[ tpg1' ]: j'a) xa` have "(i :[ tpg1' ]: j'a) xa" .
moreover have "(j'a :[ tpg_fold (tpgs1' @ tpgs2) ]: j) (ya + y)"
proof(unfold Cons(1)[OF False Cons(3)] tassemble_to.simps)
show "(EXS j'. j'a :[ tpg_fold tpgs1' ]: j' \<and>* j' :[ tpg_fold tpgs2 ]: j) (ya + y)"
proof(rule EXS_intro[where x = "j'"])
from `x ## y` `x = xa + ya` `xa ## ya`
have "ya ## y" by (metis sep_add_disjD)
moreover have "ya + y = ya + y" by simp
moreover note `(j'a :[ tpg_fold tpgs1' ]: j') ya`
`(j' :[ tpg_fold tpgs2 ]: j) y`
ultimately show "(j'a :[ tpg_fold tpgs1' ]: j' \<and>*
j' :[ tpg_fold tpgs2 ]: j) (ya + y)"
by (auto intro!:sep_conjI)
qed
qed
moreover from `s = x + y` `x = xa + ya`
have "s = xa + (ya + y)"
by (metis h(2) h(6) sep_add_assoc sep_add_disjD)
moreover from `xa ## ya` `x ## y` `x = xa + ya`
have "xa ## (ya + y)" by (metis sep_disj_addI3)
ultimately show "(i :[ tpg1' ]: j'a \<and>* j'a :[ tpg_fold (tpgs1' @ tpgs2) ]: j) s"
by (auto intro!:sep_conjI)
qed
qed
qed
thus ?thesis
by (simp add:tassemble_to.simps, unfold tpg_fold_cons[OF False],
unfold tassemble_to.simps, simp)
qed
finally show ?thesis .
next
case True
thus ?thesis
by (simp add:tpg_fold_cons[OF Cons(3)] tpg_fold_sg)
qed
qed auto
subsection {* Assertions and program logic for this assembly language *}
definition "st l = sg (tpc_set l)"
definition "ps p = sg (tpos_set p)"
definition "tm a v = sg ({TM a v})"
definition "one i = tm i Oc"
definition "zero i= tm i Bk"
definition "any i = (EXS v. tm i v)"
declare trset_of.simps[simp del]
lemma stimes_sgD:
"(sg x \<and>* q) s \<Longrightarrow> q (s - x) \<and> x \<subseteq> s"
apply(erule_tac sep_conjE)
apply(unfold set_ins_def sg_def)
by (metis Diff_Int Diff_cancel Diff_empty Un_Diff sup.cobounded1 sup_bot.left_neutral sup_commute)
lemma stD:
"(st i \<and>* r) (trset_of (ft, prog, i', pos, mem)) \<Longrightarrow> i' = i"
proof -
assume "(st i \<and>* r) (trset_of (ft, prog, i', pos, mem))"
from stimes_sgD [OF this[unfolded st_def], unfolded trset_of.simps]
have "tpc_set i \<subseteq> tprog_set prog \<union> tpc_set i' \<union> tpos_set pos \<union>
tmem_set mem \<union> tfaults_set ft" by auto
thus ?thesis
by (unfold tpn_set_def, auto)
qed
lemma psD:
"(ps p \<and>* r) (trset_of (ft, prog, i', pos, mem)) \<Longrightarrow> pos = p"
proof -
assume "(ps p ** r) (trset_of (ft, prog, i', pos, mem))"
from stimes_sgD [OF this[unfolded ps_def], unfolded trset_of.simps]
have "tpos_set p \<subseteq> tprog_set prog \<union> tpc_set i' \<union>
tpos_set pos \<union> tmem_set mem \<union> tfaults_set ft"
by simp
thus ?thesis
by (unfold tpn_set_def, auto)
qed
lemma codeD: "(st i ** sg {TC i inst} ** r) (trset_of (ft, prog, i', pos, mem))
\<Longrightarrow> prog i = Some inst"
proof -
assume "(st i ** sg {TC i inst} ** r) (trset_of (ft, prog, i', pos, mem))"
thus ?thesis
apply(unfold sep_conj_def set_ins_def sg_def trset_of.simps tpn_set_def)
by auto
qed
lemma memD: "((tm a v) ** r) (trset_of (ft, prog, i, pos, mem)) \<Longrightarrow> mem a = Some v"
proof -
assume "((tm a v) ** r) (trset_of (ft, prog, i, pos, mem))"
from stimes_sgD[OF this[unfolded trset_of.simps tpn_set_def tm_def]]
have "{TM a v} \<subseteq> {TC i inst |i inst. prog i = Some inst} \<union> {TAt i} \<union>
{TPos pos} \<union> {TM i n |i n. mem i = Some n} \<union> {TFaults ft}" by simp
thus ?thesis by auto
qed
lemma t_hoare_seq:
assumes a1: "\<And> i j. \<lbrace>st i \<and>* p\<rbrace> i:[c1]:j \<lbrace>st j \<and>* q\<rbrace>"
and a2: "\<And> j k. \<lbrace>st j ** q\<rbrace> j:[c2]:k \<lbrace>st k ** r\<rbrace>"
shows "\<lbrace>st i \<and>* p\<rbrace> i:[(c1 ; c2)]:k \<lbrace>st k \<and>* r\<rbrace>"
proof(subst tassemble_to.simps, rule tm.code_exI)
fix j'
show "\<lbrace>st i \<and>* p\<rbrace> i:[ c1 ]:j' \<and>* j':[ c2 ]:k \<lbrace>st k \<and>* r\<rbrace>"
proof(rule tm.composition)
from a1 show "\<lbrace>st i \<and>* p\<rbrace> i:[ c1 ]:j' \<lbrace>st j' \<and>* q\<rbrace>" by auto
next
from a2 show "\<lbrace>st j' \<and>* q\<rbrace> j':[ c2 ]:k \<lbrace>st k \<and>* r\<rbrace>" by auto
qed
qed
lemma t_hoare_seq1:
assumes a1: "\<And>j'. \<lbrace>st i \<and>* p\<rbrace> i:[c1]:j' \<lbrace>st j' \<and>* q\<rbrace>"
assumes a2: "\<And>j'. \<lbrace>st j' \<and>* q\<rbrace> j':[c2]:k \<lbrace>st k' \<and>* r\<rbrace>"
shows "\<lbrace>st i \<and>* p\<rbrace> i:[(c1 ; c2)]:k \<lbrace>st k' \<and>* r\<rbrace>"
proof(subst tassemble_to.simps, rule tm.code_exI)
fix j'
show "\<lbrace>st i \<and>* p\<rbrace> i:[ c1 ]:j' \<and>* j':[ c2 ]:k \<lbrace>st k' \<and>* r\<rbrace>"
proof(rule tm.composition)
from a1 show "\<lbrace>st i \<and>* p\<rbrace> i:[ c1 ]:j' \<lbrace>st j' \<and>* q\<rbrace>" by auto
next
from a2 show " \<lbrace>st j' \<and>* q\<rbrace> j':[ c2 ]:k \<lbrace>st k' \<and>* r\<rbrace>" by auto
qed
qed
lemma t_hoare_seq2:
assumes h: "\<And>j. \<lbrace>st i ** p\<rbrace> i:[c1]:j \<lbrace>st k' \<and>* r\<rbrace>"
shows "\<lbrace>st i ** p\<rbrace> i:[(c1 ; c2)]:j \<lbrace>st k' ** r\<rbrace>"
apply (unfold tassemble_to.simps, rule tm.code_exI)
by (rule tm.code_extension, rule h)
lemma t_hoare_local:
assumes h: "(\<And>l. \<lbrace>st i \<and>* p\<rbrace> i :[ c l ]: j \<lbrace>st k \<and>* q\<rbrace>)"
shows "\<lbrace>st i ** p\<rbrace> i:[TLocal c]:j \<lbrace>st k ** q\<rbrace>" using h
by (unfold tassemble_to.simps, intro tm.code_exI, simp)
lemma t_hoare_label:
assumes "\<And>l. l = i \<Longrightarrow> \<lbrace>st l \<and>* p\<rbrace> l:[ c l ]:j \<lbrace>st k \<and>* q\<rbrace>"
shows "\<lbrace>st i \<and>* p\<rbrace> i:[(TLabel l; c l)]:j \<lbrace>st k \<and>* q\<rbrace>"
using assms
by (unfold tassemble_to.simps, intro tm.code_exI tm.code_condI, clarify, auto)
primrec t_split_cmd :: "tpg \<Rightarrow> (tpg \<times> tpg option)"
where "t_split_cmd (\<guillemotright>inst) = (\<guillemotright>inst, None)" |
"t_split_cmd (TLabel l) = (TLabel l, None)" |
"t_split_cmd (TSeq c1 c2) = (case (t_split_cmd c2) of
(c21, Some c22) \<Rightarrow> (TSeq c1 c21, Some c22) |
(c21, None) \<Rightarrow> (c1, Some c21))" |
"t_split_cmd (TLocal c) = (TLocal c, None)"
definition "t_last_cmd tpg = snd (t_split_cmd tpg)"
declare t_last_cmd_def [simp]
definition "t_blast_cmd tpg = fst (t_split_cmd tpg)"
declare t_blast_cmd_def [simp]
lemma "t_last_cmd (c1; c2; TLabel l) = Some (TLabel l)"
by simp
lemma "t_blast_cmd (c1; c2; TLabel l) = (c1; c2)"
by simp
lemma t_split_cmd_eq:
assumes "t_split_cmd c = (c1, Some c2)"
shows "i:[c]:j = i:[(c1; c2)]:j"
using assms
proof(induct c arbitrary: c1 c2 i j)
case (TSeq cx cy)
from `t_split_cmd (cx ; cy) = (c1, Some c2)`
show ?case
apply (simp split:prod.splits option.splits)
apply (cases cy, auto split:prod.splits option.splits)
proof -
fix a
assume h: "t_split_cmd cy = (a, Some c2)"
show "i :[ (cx ; cy) ]: j = i :[ ((cx ; a) ; c2) ]: j"
apply (simp only: tassemble_to.simps(2) TSeq(2)[OF h] sep_conj_exists)
apply (simp add:sep_conj_ac)
by (simp add:pred_ex_def, default, auto)
qed
qed auto
lemma t_hoare_label_last_pre:
assumes h1: "t_split_cmd c = (c', Some (TLabel l))"
and h2: "l = j \<Longrightarrow> \<lbrace>p\<rbrace> i:[c']:j \<lbrace>q\<rbrace>"
shows "\<lbrace>p\<rbrace> i:[c]:j \<lbrace>q\<rbrace>"
by (unfold t_split_cmd_eq[OF h1],
simp only:tassemble_to.simps sep_conj_cond,
intro tm.code_exI tm.code_condI, insert h2, auto)
lemma t_hoare_label_last:
assumes h1: "t_last_cmd c = Some (TLabel l)"
and h2: "l = j \<Longrightarrow> \<lbrace>p\<rbrace> i:[t_blast_cmd c]:j \<lbrace>q\<rbrace>"
shows "\<lbrace>p\<rbrace> i:[c]:j \<lbrace>q\<rbrace>"
proof -
have "t_split_cmd c = (t_blast_cmd c, t_last_cmd c)"
by simp
from t_hoare_label_last_pre[OF this[unfolded h1]] h2
show ?thesis by auto
qed
subsection {* Basic assertions for TM *}
(* ones between tape position i and j *)
function ones :: "int \<Rightarrow> int \<Rightarrow> tassert" where
"ones i j = (if j < i then <(i = j + 1)>
else (one i) \<and>* ones (i + 1) j)"
by auto
termination
by (relation "measure(\<lambda> (i::int, j). nat (j - i + 1))") auto
lemma ones_base_simp:
"j < i \<Longrightarrow> ones i j = <(i = j + 1)>"
by simp
lemma ones_step_simp:
"\<not> j < i \<Longrightarrow> ones i j = ((one i) \<and>* ones (i + 1) j)"
by simp
lemmas ones_simps = ones_base_simp ones_step_simp
declare ones.simps [simp del] ones_simps [simp]
lemma ones_induct [case_names Base Step]:
assumes h1: "\<And> i j. j < i \<Longrightarrow> P i j (<(i = j + (1::int))>)"
and h2: "\<And> i j. \<lbrakk>\<not> j < i; P (i + 1) j (ones (i + 1) j)\<rbrakk> \<Longrightarrow> P i j ((one i) \<and>* ones (i + 1) j)"
shows "P i j (ones i j)"
proof(induct i j rule:ones.induct)
fix i j
assume ih: "(\<not> j < i \<Longrightarrow> P (i + 1) j (ones (i + 1) j))"
show "P i j (ones i j)"
proof(cases "j < i")
case True
with h1 [OF True]
show ?thesis by auto
next
case False
from h2 [OF False] and ih[OF False]
have "P i j (one i \<and>* ones (i + 1) j)" by blast
with False show ?thesis by auto
qed
qed
function ones' :: "int \<Rightarrow> int \<Rightarrow> tassert" where
"ones' i j = (if j < i then <(i = j + 1)>
else ones' i (j - 1) \<and>* one j)"
by auto
termination by (relation "measure(\<lambda> (i::int, j). nat (j - i + 1))") auto
lemma ones_rev: "\<not> j < i \<Longrightarrow> (ones i j) = ((ones i (j - 1)) ** one j)"
proof(induct i j rule:ones_induct)
case Base
thus ?case by auto
next
case (Step i j)
show ?case
proof(cases "j < i + 1")
case True
with Step show ?thesis
by simp
next
case False
with Step show ?thesis
by (auto simp:sep_conj_ac)
qed
qed
lemma ones_rev_induct [case_names Base Step]:
assumes h1: "\<And> i j. j < i \<Longrightarrow> P i j (<(i = j + (1::int))>)"
and h2: "\<And> i j. \<lbrakk>\<not> j < i; P i (j - 1) (ones i (j - 1))\<rbrakk> \<Longrightarrow> P i j ((ones i (j - 1)) ** one j)"
shows "P i j (ones i j)"
proof(induct i j rule:ones'.induct)
fix i j
assume ih: "(\<not> j < i \<Longrightarrow> P i (j - 1) (ones i (j - 1)))"
show "P i j (ones i j)"
proof(cases "j < i")
case True
with h1 [OF True]
show ?thesis by auto
next
case False
from h2 [OF False] and ih[OF False]
have "P i j (ones i (j - 1) \<and>* one j)" by blast
with ones_rev and False
show ?thesis
by simp
qed
qed
function zeros :: "int \<Rightarrow> int \<Rightarrow> tassert" where
"zeros i j = (if j < i then <(i = j + 1)> else
(zero i) ** zeros (i + 1) j)"
by auto
termination by (relation "measure(\<lambda> (i::int, j). nat (j - i + 1))") auto
lemma zeros_base_simp: "j < i \<Longrightarrow> zeros i j = <(i = j + 1)>"
by simp
lemma zeros_step_simp: "\<not> j < i \<Longrightarrow> zeros i j = ((zero i) ** zeros (i + 1) j)"
by simp
declare zeros.simps [simp del]
lemmas zeros_simps [simp] = zeros_base_simp zeros_step_simp
lemma zeros_induct [case_names Base Step]:
assumes h1: "\<And> i j. j < i \<Longrightarrow> P i j (<(i = j + (1::int))>)"
and h2: "\<And> i j. \<lbrakk>\<not> j < i; P (i + 1) j (zeros (i + 1) j)\<rbrakk> \<Longrightarrow>
P i j ((zero i) ** zeros (i + 1) j)"
shows "P i j (zeros i j)"
proof(induct i j rule:zeros.induct)
fix i j
assume ih: "(\<not> j < i \<Longrightarrow> P (i + 1) j (zeros (i + 1) j))"
show "P i j (zeros i j)"
proof(cases "j < i")
case True
with h1 [OF True]
show ?thesis by auto
next
case False
from h2 [OF False] and ih[OF False]
have "P i j (zero i \<and>* zeros (i + 1) j)" by blast
with False show ?thesis by auto
qed
qed
lemma zeros_rev: "\<not> j < i \<Longrightarrow> (zeros i j) = ((zeros i (j - 1)) \<and>* zero j)"
proof(induct i j rule:zeros_induct)
case (Base i j)
thus ?case by auto
next
case (Step i j)
show ?case
proof(cases "j < i + 1")
case True
with Step show ?thesis by auto
next
case False
with Step show ?thesis by (auto simp:sep_conj_ac)
qed
qed
lemma zeros_rev_induct [case_names Base Step]:
assumes h1: "\<And> i j. j < i \<Longrightarrow> P i j (<(i = j + (1::int))>)"
and h2: "\<And> i j. \<lbrakk>\<not> j < i; P i (j - 1) (zeros i (j - 1))\<rbrakk> \<Longrightarrow>
P i j ((zeros i (j - 1)) ** zero j)"
shows "P i j (zeros i j)"
proof(induct i j rule:ones'.induct)
fix i j
assume ih: "(\<not> j < i \<Longrightarrow> P i (j - 1) (zeros i (j - 1)))"
show "P i j (zeros i j)"
proof(cases "j < i")
case True
with h1 [OF True]
show ?thesis by auto
next
case False
from h2 [OF False] and ih[OF False]
have "P i j (zeros i (j - 1) \<and>* zero j)" by blast
with zeros_rev and False
show ?thesis by simp
qed
qed
definition "rep i j k = ((ones i (i + (int k))) \<and>* <(j = i + int k)>)"
fun reps :: "int \<Rightarrow> int \<Rightarrow> nat list\<Rightarrow> tassert"
where
"reps i j [] = <(i = j + 1)>" |
"reps i j [k] = (ones i (i + int k) ** <(j = i + int k)>)" |
"reps i j (k # ks) = (ones i (i + int k) ** zero (i + int k + 1) ** reps (i + int k + 2) j ks)"
lemma reps_simp3: "ks \<noteq> [] \<Longrightarrow>
reps i j (k # ks) = (ones i (i + int k) ** zero (i + int k + 1) ** reps (i + int k + 2) j ks)"
by (cases ks, auto)
definition "reps_sep_len ks = (if length ks \<le> 1 then 0 else (length ks) - 1)"
definition "reps_ctnt_len ks = (\<Sum> k \<leftarrow> ks. (1 + k))"
definition "reps_len ks = (reps_sep_len ks) + (reps_ctnt_len ks)"
definition "splited xs ys zs = ((xs = ys @ zs) \<and> (ys \<noteq> []) \<and> (zs \<noteq> []))"
lemma list_split:
assumes h: "k # ks = ys @ zs"
and h1: "ys \<noteq> []"
shows "(ys = [k] \<and> zs = ks) \<or> (\<exists> ys'. ys' \<noteq> [] \<and> ys = k # ys' \<and> ks = ys' @ zs)"
proof(cases ys)
case Nil
with h1 show ?thesis by auto
next
case (Cons y' ys')
with h have "k#ks = y'#(ys' @ zs)" by simp
hence hh: "y' = k" "ks = ys' @ zs" by auto
show ?thesis
proof(cases "ys' = []")
case False
show ?thesis
proof(rule disjI2)
show " \<exists>ys'. ys' \<noteq> [] \<and> ys = k # ys' \<and> ks = ys' @ zs"
proof(rule exI[where x = ys'])
from False hh Cons show "ys' \<noteq> [] \<and> ys = k # ys' \<and> ks = ys' @ zs" by auto
qed
qed
next
case True
show ?thesis
proof(rule disjI1)
from hh True Cons
show "ys = [k] \<and> zs = ks" by auto
qed
qed
qed
lemma splited_cons[elim_format]:
assumes h: "splited (k # ks) ys zs"
shows "(ys = [k] \<and> zs = ks) \<or> (\<exists> ys'. ys' \<noteq> [] \<and> ys = k # ys' \<and> splited ks ys' zs)"
proof -
from h have "k # ks = ys @ zs" "ys \<noteq> [] " unfolding splited_def by auto
from list_split[OF this]
have "ys = [k] \<and> zs = ks \<or> (\<exists>ys'. ys' \<noteq> [] \<and> ys = k # ys' \<and> ks = ys' @ zs)" .
thus ?thesis
proof
assume " ys = [k] \<and> zs = ks" thus ?thesis by auto
next
assume "\<exists>ys'. ys' \<noteq> [] \<and> ys = k # ys' \<and> ks = ys' @ zs"
then obtain ys' where hh: "ys' \<noteq> []" "ys = k # ys'" "ks = ys' @ zs" by auto
show ?thesis
proof(rule disjI2)
show "\<exists>ys'. ys' \<noteq> [] \<and> ys = k # ys' \<and> splited ks ys' zs"
proof(rule exI[where x = ys'])
from h have "zs \<noteq> []" by (unfold splited_def, simp)
with hh(1) hh(3)
have "splited ks ys' zs"
by (unfold splited_def, auto)
with hh(1) hh(2) show "ys' \<noteq> [] \<and> ys = k # ys' \<and> splited ks ys' zs" by auto
qed
qed
qed
qed
lemma splited_cons_elim:
assumes h: "splited (k # ks) ys zs"
and h1: "\<lbrakk>ys = [k]; zs = ks\<rbrakk> \<Longrightarrow> P"
and h2: "\<And> ys'. \<lbrakk>ys' \<noteq> []; ys = k#ys'; splited ks ys' zs\<rbrakk> \<Longrightarrow> P"
shows P
proof(rule splited_cons[OF h])
assume "ys = [k] \<and> zs = ks \<or> (\<exists>ys'. ys' \<noteq> [] \<and> ys = k # ys' \<and> splited ks ys' zs)"
thus P
proof
assume hh: "ys = [k] \<and> zs = ks"
show P
proof(rule h1)
from hh show "ys = [k]" by simp
next
from hh show "zs = ks" by simp
qed
next
assume "\<exists>ys'. ys' \<noteq> [] \<and> ys = k # ys' \<and> splited ks ys' zs"
then obtain ys' where hh: "ys' \<noteq> []" "ys = k # ys'" "splited ks ys' zs" by auto
from h2[OF this]
show P .
qed
qed
lemma list_nth_expand:
"i < length xs \<Longrightarrow> xs = take i xs @ [xs!i] @ drop (Suc i) xs"
by (metis Cons_eq_appendI append_take_drop_id drop_Suc_conv_tl eq_Nil_appendI)
lemma reps_len_nil: "reps_len [] = 0"
by (auto simp:reps_len_def reps_sep_len_def reps_ctnt_len_def)
lemma reps_len_sg: "reps_len [k] = 1 + k"
by (auto simp:reps_len_def reps_sep_len_def reps_ctnt_len_def)
lemma reps_len_cons: "ks \<noteq> [] \<Longrightarrow> (reps_len (k # ks)) = 2 + k + reps_len ks "
proof(induct ks arbitrary:k)
case (Cons n ns)
thus ?case
by(cases "ns = []",
auto simp:reps_len_def reps_sep_len_def reps_ctnt_len_def)
qed auto
lemma reps_len_correct:
assumes h: "(reps i j ks) s"
shows "j = i + int (reps_len ks) - 1"
using h
proof(induct ks arbitrary:i j s)
case Nil
thus ?case
by (auto simp:reps_len_nil pasrt_def)
next
case (Cons n ns)
thus ?case
proof(cases "ns = []")
case False
from Cons(2)[unfolded reps_simp3[OF False]]
obtain s' where "(reps (i + int n + 2) j ns) s'"
by (auto elim!:sep_conjE)
from Cons.hyps[OF this]
show ?thesis
by (unfold reps_len_cons[OF False], simp)
next
case True
with Cons(2)
show ?thesis
by (auto simp:reps_len_sg pasrt_def)
qed
qed
lemma reps_len_expand:
shows "(EXS j. (reps i j ks)) = (reps i (i + int (reps_len ks) - 1) ks)"
proof(default+)
fix s
assume "(EXS j. reps i j ks) s"
with reps_len_correct show "reps i (i + int (reps_len ks) - 1) ks s"
by (auto simp:pred_ex_def)
next
fix s
assume "reps i (i + int (reps_len ks) - 1) ks s"
thus "(EXS j. reps i j ks) s" by (auto simp:pred_ex_def)
qed
lemma reps_len_expand1: "(EXS j. (reps i j ks \<and>* r)) = (reps i (i + int (reps_len ks) - 1) ks \<and>* r)"
by (metis reps_len_def reps_len_expand sep.mult_commute sep_conj_exists1)
lemma reps_splited:
assumes h: "splited xs ys zs"
shows "reps i j xs = (reps i (i + int (reps_len ys) - 1) ys \<and>*
zero (i + int (reps_len ys)) \<and>*
reps (i + int (reps_len ys) + 1) j zs)"
using h
proof(induct xs arbitrary: i j ys zs)
case Nil
thus ?case
by (unfold splited_def, auto)
next
case (Cons k ks)
from Cons(2)
show ?case
proof(rule splited_cons_elim)
assume h: "ys = [k]" "zs = ks"
with Cons(2)
show ?thesis
proof(cases "ks = []")
case True
with Cons(2) have False
by (simp add:splited_def, cases ys, auto)
thus ?thesis by auto
next
case False
have ss: "i + int k + 1 = i + (1 + int k)"
"i + int k + 2 = 2 + (i + int k)" by auto
show ?thesis
by (unfold h(1), unfold reps_simp3[OF False] reps.simps(2)
reps_len_sg, auto simp:sep_conj_ac,
unfold ss h(2), simp)
qed
next
fix ys'
assume h: "ys' \<noteq> []" "ys = k # ys'" "splited ks ys' zs"
hence nnks: "ks \<noteq> []"
by (unfold splited_def, auto)
have ss: "i + int k + 2 + int (reps_len ys') =
i + (2 + (int k + int (reps_len ys')))" by auto
show ?thesis
by (simp add: reps_simp3[OF nnks] reps_simp3[OF h(1)]
Cons(1)[OF h(3)] h(2)
reps_len_cons[OF h(1)]
sep_conj_ac, subst ss, simp)
qed
qed
subsection {* A theory of list extension *}
definition "list_ext n xs = xs @ replicate ((Suc n) - length xs) 0"
lemma list_ext_len_eq: "length (list_ext a xs) = length xs + (Suc a - length xs)"
by (metis length_append length_replicate list_ext_def)
lemma list_ext_len: "a < length (list_ext a xs)"
by (unfold list_ext_len_eq, auto)
lemma list_ext_lt: "a < length xs \<Longrightarrow> list_ext a xs = xs"
by (smt append_Nil2 list_ext_def replicate_0)
lemma list_ext_lt_get:
assumes h: "a' < length xs"
shows "(list_ext a xs)!a' = xs!a'"
proof(cases "a < length xs")
case True
with h
show ?thesis by (auto simp:list_ext_lt)
next
case False
with h show ?thesis
apply (unfold list_ext_def)
by (metis nth_append)
qed
lemma list_ext_get_upd: "((list_ext a xs)[a:=v])!a = v"
by (metis list_ext_len nth_list_update_eq)
lemma nth_app: "length xs \<le> a \<Longrightarrow> (xs @ ys)!a = ys!(a - length xs)"
by (metis not_less nth_append)
lemma list_ext_tail:
assumes h1: "length xs \<le> a"
and h2: "length xs \<le> a'"
and h3: "a' \<le> a"
shows "(list_ext a xs)!a' = 0"
proof -
from h1 h2
have "a' - length xs < length (replicate (Suc a - length xs) 0)"
by (metis diff_less_mono h3 le_imp_less_Suc length_replicate)
moreover from h1 have "replicate (Suc a - length xs) 0 \<noteq> []"
by (smt empty_replicate)
ultimately have "(replicate (Suc a - length xs) 0)!(a' - length xs) = 0"
by (metis length_replicate nth_replicate)
moreover have "(xs @ (replicate (Suc a - length xs) 0))!a' =
(replicate (Suc a - length xs) 0)!(a' - length xs)"
by (rule nth_app[OF h2])
ultimately show ?thesis
by (auto simp:list_ext_def)
qed
lemmas list_ext_simps = list_ext_lt_get list_ext_lt list_ext_len list_ext_len_eq
lemma listsum_upd_suc:
"a < length ks \<Longrightarrow> listsum (map Suc (ks[a := Suc (ks ! a)]))= (Suc (listsum (map Suc ks)))"
by (smt elem_le_listsum_nat
length_list_update list_ext_get_upd
list_update_overwrite listsum_update_nat map_update
nth_equalityI nth_list_update nth_map)
lemma reps_len_suc:
assumes "a < length ks"
shows "reps_len (ks[a:=Suc(ks!a)]) = 1 + reps_len ks"
proof(cases "length ks \<le> 1")
case True
with `a < length ks`
obtain k where "ks = [k]" "a = 0"
by (smt length_0_conv length_Suc_conv)
thus ?thesis
apply (unfold `ks = [k]` `a = 0`)
by (unfold reps_len_def reps_sep_len_def reps_ctnt_len_def, auto)
next
case False
have "Suc = (op + (Suc 0))"
by (default, auto)
with listsum_upd_suc[OF `a < length ks`] False
show ?thesis
by (unfold reps_len_def reps_sep_len_def reps_ctnt_len_def, simp)
qed
lemma ks_suc_len:
assumes h1: "(reps i j ks) s"
and h2: "ks!a = v"
and h3: "a < length ks"
and h4: "(reps i j' (ks[a:=Suc v])) s'"
shows "j' = j + int (reps_len (list_ext a ks)) - int (reps_len ks) + 1"
proof -
from reps_len_correct[OF h1, unfolded list_ext_len_eq]
reps_len_correct[OF h4, unfolded list_ext_len_eq]
reps_len_suc[OF `a < length ks`] h2 h3
show ?thesis
by (unfold list_ext_lt[OF `a < length ks`], auto)
qed
lemma ks_ext_len:
assumes h1: "(reps i j ks) s"
and h3: "length ks \<le> a"
and h4: "reps i j' (list_ext a ks) s'"
shows "j' = j + int (reps_len (list_ext a ks)) - int (reps_len ks)"
proof -
from reps_len_correct[OF h1, unfolded list_ext_len_eq]
and reps_len_correct[OF h4, unfolded list_ext_len_eq]
h3
show ?thesis by auto
qed
definition
"reps' i j ks =
(if ks = [] then (<(i = j + 1)>) else (reps i (j - 1) ks \<and>* zero j))"
lemma reps'_expand:
assumes h: "ks \<noteq> []"
shows "(EXS j. reps' i j ks) = reps' i (i + int (reps_len ks)) ks"
proof -
show ?thesis
proof(default+)
fix s
assume "(EXS j. reps' i j ks) s"
with h have "(EXS j. reps i (j - 1) ks \<and>* zero j) s"
by (simp add:reps'_def)
hence "(reps i (i + int (reps_len ks) - 1) ks \<and>* zero (i + int (reps_len ks))) s"
proof(elim EXS_elim)
fix j
assume "(reps i (j - 1) ks \<and>* zero j) s"
then obtain s1 s2 where "s = s1 + s2" "s1 ## s2" "reps i (j - 1) ks s1" "zero j s2"
by (auto elim!:sep_conjE)
from reps_len_correct[OF this(3)]
have "j = i + int (reps_len ks)" by auto
with `reps i (j - 1) ks s1` have "reps i (i + int (reps_len ks) - 1) ks s1"
by simp
moreover from `j = i + int (reps_len ks)` and `zero j s2`
have "zero (i + int (reps_len ks)) s2" by auto
ultimately show "(reps i (i + int (reps_len ks) - 1) ks \<and>* zero (i + int (reps_len ks))) s"
using `s = s1 + s2` `s1 ## s2` by (auto intro!:sep_conjI)
qed
thus "reps' i (i + int (reps_len ks)) ks s"
by (simp add:h reps'_def)
next
fix s
assume "reps' i (i + int (reps_len ks)) ks s"
thus "(EXS j. reps' i j ks) s"
by (auto intro!:EXS_intro)
qed
qed
lemma reps'_len_correct:
assumes h: "(reps' i j ks) s"
and h1: "ks \<noteq> []"
shows "(j = i + int (reps_len ks))"
proof -
from h1 have "reps' i j ks s = (reps i (j - 1) ks \<and>* zero j) s" by (simp add:reps'_def)
from h[unfolded this]
obtain s' where "reps i (j - 1) ks s'"
by (auto elim!:sep_conjE)
from reps_len_correct[OF this]
show ?thesis by simp
qed
lemma reps'_append:
"reps' i j (ks1 @ ks2) = (EXS m. (reps' i (m - 1) ks1 \<and>* reps' m j ks2))"
proof(cases "ks1 = []")
case True
thus ?thesis
by (auto simp:reps'_def pred_ex_def pasrt_def set_ins_def sep_conj_def)
next
case False
show ?thesis
proof(cases "ks2 = []")
case False
from `ks1 \<noteq> []` and `ks2 \<noteq> []`
have "splited (ks1 @ ks2) ks1 ks2" by (auto simp:splited_def)
from reps_splited[OF this, of i "j - 1"]
have eq_1: "reps i (j - 1) (ks1 @ ks2) =
(reps i (i + int (reps_len ks1) - 1) ks1 \<and>*
zero (i + int (reps_len ks1)) \<and>*
reps (i + int (reps_len ks1) + 1) (j - 1) ks2)" .
from `ks1 \<noteq> []`
have eq_2: "reps' i j (ks1 @ ks2) = (reps i (j - 1) (ks1 @ ks2) \<and>* zero j)"
by (unfold reps'_def, simp)
show ?thesis
proof(default+)
fix s
assume "reps' i j (ks1 @ ks2) s"
show "(EXS m. reps' i (m - 1) ks1 \<and>* reps' m j ks2) s"
proof(rule EXS_intro[where x = "i + int(reps_len ks1) + 1"])
from `reps' i j (ks1 @ ks2) s`[unfolded eq_2 eq_1]
and `ks1 \<noteq> []` `ks2 \<noteq> []`
show "(reps' i (i + int (reps_len ks1) + 1 - 1) ks1 \<and>*
reps' (i + int (reps_len ks1) + 1) j ks2) s"
by (unfold reps'_def, simp, sep_cancel+)
qed
next
fix s
assume "(EXS m. reps' i (m - 1) ks1 \<and>* reps' m j ks2) s"
thus "reps' i j (ks1 @ ks2) s"
proof(elim EXS_elim)
fix m
assume "(reps' i (m - 1) ks1 \<and>* reps' m j ks2) s"
then obtain s1 s2 where h:
"s = s1 + s2" "s1 ## s2" "reps' i (m - 1) ks1 s1"
" reps' m j ks2 s2" by (auto elim!:sep_conjE)
from reps'_len_correct[OF this(3) `ks1 \<noteq> []`]
have eq_m: "m = i + int (reps_len ks1) + 1" by simp
have "((reps i (i + int (reps_len ks1) - 1) ks1 \<and>* zero (i + int (reps_len ks1))) \<and>*
((reps (i + int (reps_len ks1) + 1) (j - 1) ks2) \<and>* zero j)) s"
(is "(?P \<and>* ?Q) s")
proof(rule sep_conjI)
from h(3) eq_m `ks1 \<noteq> []` show "?P s1"
by (simp add:reps'_def)
next
from h(4) eq_m `ks2 \<noteq> []` show "?Q s2"
by (simp add:reps'_def)
next
from h(2) show "s1 ## s2" .
next
from h(1) show "s = s1 + s2" .
qed
thus "reps' i j (ks1 @ ks2) s"
by (unfold eq_2 eq_1, auto simp:sep_conj_ac)
qed
qed
next
case True
have "-1 + j = j - 1" by auto
with `ks1 \<noteq> []` True
show ?thesis
apply (auto simp:reps'_def pred_ex_def pasrt_def)
apply (unfold `-1 + j = j - 1`)
by (fold sep_empty_def, simp only:sep_conj_empty)
qed
qed
lemma reps'_sg:
"reps' i j [k] =
(<(j = i + int k + 1)> \<and>* ones i (i + int k) \<and>* zero j)"
apply (unfold reps'_def, default, auto simp:sep_conj_ac)
by (sep_cancel+, simp add:pasrt_def)+
section {* Basic macros for TM *}
definition "write_zero = (TL exit. \<guillemotright>((W0, exit), (W0, exit)); TLabel exit)"
lemma st_upd:
assumes pre: "(st i' ** r) (trset_of (f, x, i, y, z))"
shows "(st i'' ** r) (trset_of (f, x, i'', y, z))"
proof -
from stimes_sgD[OF pre[unfolded st_def], unfolded trset_of.simps, unfolded stD[OF pre]]
have "r (tprog_set x \<union> tpc_set i' \<union> tpos_set y \<union> tmem_set z \<union> tfaults_set f - tpc_set i')"
by blast
moreover have
"(tprog_set x \<union> tpc_set i' \<union> tpos_set y \<union> tmem_set z \<union> tfaults_set f - tpc_set i') =
(tprog_set x \<union> tpos_set y \<union> tmem_set z \<union> tfaults_set f)"
by (unfold tpn_set_def, auto)
ultimately have r_rest: "r (tprog_set x \<union> tpos_set y \<union> tmem_set z \<union> tfaults_set f)"
by auto
show ?thesis
proof(rule sep_conjI[where Q = r, OF _ r_rest])
show "st i'' (tpc_set i'')"
by (unfold st_def sg_def, simp)
next
show "tpc_set i'' ## tprog_set x \<union> tpos_set y \<union> tmem_set z \<union> tfaults_set f"
by (unfold tpn_set_def sep_disj_set_def, auto)
next
show "trset_of (f, x, i'', y, z) =
tpc_set i'' + (tprog_set x \<union> tpos_set y \<union> tmem_set z \<union> tfaults_set f)"
by (unfold trset_of.simps plus_set_def, auto)
qed
qed
lemma pos_upd:
assumes pre: "(ps i ** r) (trset_of (f, x, y, i', z))"
shows "(ps j ** r) (trset_of (f, x, y, j, z))"
proof -
from stimes_sgD[OF pre[unfolded ps_def], unfolded trset_of.simps, unfolded psD[OF pre]]
have "r (tprog_set x \<union> tpc_set y \<union> tpos_set i \<union> tmem_set z \<union>
tfaults_set f - tpos_set i)" (is "r ?xs")
by blast
moreover have
"?xs = tprog_set x \<union> tpc_set y \<union> tmem_set z \<union> tfaults_set f"
by (unfold tpn_set_def, auto)
ultimately have r_rest: "r \<dots>"
by auto
show ?thesis
proof(rule sep_conjI[where Q = r, OF _ r_rest])
show "ps j (tpos_set j)"
by (unfold ps_def sg_def, simp)
next
show "tpos_set j ## tprog_set x \<union> tpc_set y \<union> tmem_set z \<union> tfaults_set f"
by (unfold tpn_set_def sep_disj_set_def, auto)
next
show "trset_of (f, x, y, j, z) =
tpos_set j + (tprog_set x \<union> tpc_set y \<union> tmem_set z \<union> tfaults_set f)"
by (unfold trset_of.simps plus_set_def, auto)
qed
qed
lemma TM_in_simp: "({TM a v} \<subseteq>
tprog_set x \<union> tpc_set y \<union> tpos_set z \<union> tmem_set mem \<union> tfaults_set f) =
({TM a v} \<subseteq> tmem_set mem)"
by (unfold tpn_set_def, auto)
lemma tmem_set_upd:
"{TM a v} \<subseteq> tmem_set mem \<Longrightarrow>
tmem_set (mem(a:=Some v')) = ((tmem_set mem) - {TM a v}) \<union> {TM a v'}"
by (unfold tpn_set_def, auto)
lemma tmem_set_disj: "{TM a v} \<subseteq> tmem_set mem \<Longrightarrow>
{TM a v'} \<inter> (tmem_set mem - {TM a v}) = {}"
by (unfold tpn_set_def, auto)
lemma smem_upd: "((tm a v) ** r) (trset_of (f, x, y, z, mem)) \<Longrightarrow>
((tm a v') ** r) (trset_of (f, x, y, z, mem(a := Some v')))"
proof -
have eq_s: "(tprog_set x \<union> tpc_set y \<union> tpos_set z \<union> tmem_set mem \<union> tfaults_set f - {TM a v}) =
(tprog_set x \<union> tpc_set y \<union> tpos_set z \<union> (tmem_set mem - {TM a v}) \<union> tfaults_set f)"
by (unfold tpn_set_def, auto)
assume g: "(tm a v \<and>* r) (trset_of (f, x, y, z, mem))"
from this[unfolded trset_of.simps tm_def]
have h: "(sg {TM a v} \<and>* r) (tprog_set x \<union> tpc_set y \<union> tpos_set z \<union> tmem_set mem \<union> tfaults_set f)" .
hence h0: "r (tprog_set x \<union> tpc_set y \<union> tpos_set z \<union> (tmem_set mem - {TM a v}) \<union> tfaults_set f)"
by(sep_drule stimes_sgD, clarify, unfold eq_s, auto)
from h TM_in_simp have "{TM a v} \<subseteq> tmem_set mem"
by(sep_drule stimes_sgD, auto)
from tmem_set_upd [OF this] tmem_set_disj[OF this]
have h2: "tmem_set (mem(a \<mapsto> v')) = {TM a v'} \<union> (tmem_set mem - {TM a v})"
"{TM a v'} \<inter> (tmem_set mem - {TM a v}) = {}" by auto
show ?thesis
proof -
have "(tm a v' ** r) (tmem_set (mem(a \<mapsto> v')) \<union> tprog_set x \<union> tpc_set y \<union> tpos_set z \<union> tfaults_set f)"
proof(rule sep_conjI)
show "tm a v' ({TM a v'})" by (unfold tm_def sg_def, simp)
next
from h0 show "r (tprog_set x \<union> tpc_set y \<union> tpos_set z \<union> (tmem_set mem - {TM a v}) \<union> tfaults_set f)" .
next
show "{TM a v'} ## tprog_set x \<union> tpc_set y \<union> tpos_set z \<union> (tmem_set mem - {TM a v}) \<union> tfaults_set f"
proof -
from g have " mem a = Some v"
by(sep_frule memD, simp)
thus "?thesis"
by(unfold tpn_set_def set_ins_def, auto)
qed
next
show "tmem_set (mem(a \<mapsto> v')) \<union> tprog_set x \<union> tpc_set y \<union> tpos_set z \<union> tfaults_set f =
{TM a v'} + (tprog_set x \<union> tpc_set y \<union> tpos_set z \<union> (tmem_set mem - {TM a v}) \<union> tfaults_set f)"
by (unfold h2(1) set_ins_def eq_s, auto)
qed
thus ?thesis
apply (unfold trset_of.simps)
by (metis sup_commute sup_left_commute)
qed
qed
lemma hoare_write_zero:
"\<lbrace>st i ** ps p ** tm p v\<rbrace>
i:[write_zero]:j
\<lbrace>st j ** ps p ** tm p Bk\<rbrace>"
proof(unfold write_zero_def, intro t_hoare_local, rule t_hoare_label_last, simp, simp)
show "\<lbrace>st i \<and>* ps p \<and>* tm p v\<rbrace> i :[ \<guillemotright> ((W0, j), W0, j) ]: j \<lbrace>st j \<and>* ps p \<and>* tm p Bk\<rbrace>"
proof(unfold tassemble_to.simps, simp only:sep_conj_cond,
intro tm.code_condI, simp)
assume eq_j: "j = Suc i"
show "\<lbrace>st i \<and>* ps p \<and>* tm p v\<rbrace> sg {TC i ((W0, Suc i), W0, Suc i)}
\<lbrace>st (Suc i) \<and>* ps p \<and>* tm p Bk\<rbrace>"
proof(fold eq_j, unfold tassemble_to.simps tm.Hoare_gen_def sep_conj_ac, clarify)
fix ft prog cs i' mem r
assume h: "(r \<and>* ps p \<and>* st i \<and>* tm p v \<and>* sg {TC i ((W0, j), W0, j)})
(trset_of (ft, prog, cs, i', mem))"
from h have "prog i = Some ((W0, j), W0, j)"
apply(rule_tac r = "r \<and>* ps p \<and>* tm p v" in codeD)
by(simp add: sep_conj_ac)
from h and this have stp:
"tm.run 1 (ft, prog, cs, i', mem) = (ft, prog, j, i', mem(i'\<mapsto> Bk))" (is "?x = ?y")
apply(sep_frule psD)
apply(sep_frule stD)
apply(sep_frule memD, simp)
by(cases v, unfold tm.run_def, auto)
from h have "i' = p"
by(sep_drule psD, simp)
with h
have "(r \<and>* ps p \<and>* st j \<and>* tm p Bk \<and>* sg {TC i ((W0, j), W0, j)}) (trset_of ?x)"
apply(unfold stp)
apply(sep_drule pos_upd, sep_drule st_upd, sep_drule smem_upd)
apply(auto simp: sep_conj_ac)
done
thus "\<exists>k. (r \<and>* ps p \<and>* st j \<and>* tm p Bk \<and>* sg {TC i ((W0, j), W0, j)})
(trset_of (tm.run (Suc k) (ft, prog, cs, i', mem)))"
apply (rule_tac x = 0 in exI)
by auto
qed
qed
qed
lemma hoare_write_zero_gen[step]:
assumes "p = q"
shows "\<lbrace>st i ** ps p ** tm q v\<rbrace>
i:[write_zero]:j
\<lbrace>st j ** ps p ** tm q Bk\<rbrace>"
by (unfold assms, rule hoare_write_zero)
definition "write_one = (TL exit. \<guillemotright>((W1, exit), (W1, exit)); TLabel exit)"
lemma hoare_write_one:
"\<lbrace>st i ** ps p ** tm p v\<rbrace>
i:[write_one]:j
\<lbrace>st j ** ps p ** tm p Oc\<rbrace>"
proof(unfold write_one_def, intro t_hoare_local, rule t_hoare_label_last, simp+)
fix l
show "\<lbrace>st i \<and>* ps p \<and>* tm p v\<rbrace> i :[ \<guillemotright> ((W1, j), W1, j) ]: j \<lbrace>st j \<and>* ps p \<and>* tm p Oc\<rbrace>"
proof(unfold tassemble_to.simps, simp only:sep_conj_cond,
rule_tac tm.code_condI, simp add: sep_conj_ac)
let ?j = "Suc i"
show "\<lbrace>ps p \<and>* st i \<and>* tm p v\<rbrace> sg {TC i ((W1, ?j), W1, ?j)}
\<lbrace>ps p \<and>* st ?j \<and>* tm p Oc\<rbrace>"
proof(unfold tassemble_to.simps tm.Hoare_gen_def sep_conj_ac, clarify)
fix ft prog cs i' mem r
assume h: "(r \<and>* ps p \<and>* st i \<and>* tm p v \<and>* sg {TC i ((W1, ?j), W1, ?j)})
(trset_of (ft, prog, cs, i', mem))"
from h have "prog i = Some ((W1, ?j), W1, ?j)"
apply(rule_tac r = "r \<and>* ps p \<and>* tm p v" in codeD)
by(simp add: sep_conj_ac)
from h and this have stp:
"tm.run 1 (ft, prog, cs, i', mem) =
(ft, prog, ?j, i', mem(i'\<mapsto> Oc))" (is "?x = ?y")
apply(sep_frule psD)
apply(sep_frule stD)
apply(sep_frule memD, simp)
by(cases v, unfold tm.run_def, auto)
from h have "i' = p"
by(sep_drule psD, simp)
with h
have "(r \<and>* ps p \<and>* st ?j \<and>* tm p Oc \<and>* sg {TC i ((W1, ?j), W1, ?j)}) (trset_of ?x)"
apply(unfold stp)
apply(sep_drule pos_upd, sep_drule st_upd, sep_drule smem_upd)
apply(auto simp: sep_conj_ac)
done
thus "\<exists>k. (r \<and>* ps p \<and>* st ?j \<and>* tm p Oc \<and>* sg {TC i ((W1, ?j), W1, ?j)})
(trset_of (tm.run (Suc k) (ft, prog, cs, i', mem)))"
apply (rule_tac x = 0 in exI)
by auto
qed
qed
qed
lemma hoare_write_one_gen[step]:
assumes "p = q"
shows "\<lbrace>st i ** ps p ** tm q v\<rbrace>
i:[write_one]:j
\<lbrace>st j ** ps p ** tm q Oc\<rbrace>"
by (unfold assms, rule hoare_write_one)
definition "move_left = (TL exit . \<guillemotright>((L, exit), (L, exit)); TLabel exit)"
lemma hoare_move_left:
"\<lbrace>st i ** ps p ** tm p v2\<rbrace>
i:[move_left]:j
\<lbrace>st j ** ps (p - 1) ** tm p v2\<rbrace>"
proof(unfold move_left_def, intro t_hoare_local, rule t_hoare_label_last, simp+)
fix l
show "\<lbrace>st i \<and>* ps p \<and>* tm p v2\<rbrace> i :[ \<guillemotright> ((L, l), L, l) ]: l
\<lbrace>st l \<and>* ps (p - 1) \<and>* tm p v2\<rbrace>"
proof(unfold tassemble_to.simps, simp only:sep_conj_cond,
intro tm.code_condI, simp add: sep_conj_ac)
let ?j = "Suc i"
show "\<lbrace>ps p \<and>* st i \<and>* tm p v2\<rbrace> sg {TC i ((L, ?j), L, ?j)}
\<lbrace>st ?j \<and>* tm p v2 \<and>* ps (p - 1)\<rbrace>"
proof(unfold tassemble_to.simps tm.Hoare_gen_def sep_conj_ac, clarify)
fix ft prog cs i' mem r
assume h: "(r \<and>* ps p \<and>* st i \<and>* tm p v2 \<and>* sg {TC i ((L, ?j), L, ?j)})
(trset_of (ft, prog, cs, i', mem))"
from h have "prog i = Some ((L, ?j), L, ?j)"
apply(rule_tac r = "r \<and>* ps p \<and>* tm p v2" in codeD)
by(simp add: sep_conj_ac)
from h and this have stp:
"tm.run 1 (ft, prog, cs, i', mem) = (ft, prog, ?j, i' - 1, mem)" (is "?x = ?y")
apply(sep_frule psD)
apply(sep_frule stD)
apply(sep_frule memD, simp)
apply(unfold tm.run_def, case_tac v2, auto)
done
from h have "i' = p"
by(sep_drule psD, simp)
with h
have "(r \<and>* st ?j \<and>* tm p v2 \<and>* ps (p - 1) \<and>* sg {TC i ((L, ?j), L, ?j)})
(trset_of ?x)"
apply(unfold stp)
apply(sep_drule pos_upd, sep_drule st_upd, simp)
proof -
assume "(st ?j \<and>* ps (p - 1) \<and>* r \<and>* tm p v2 \<and>* sg {TC i ((L, ?j), L, ?j)})
(trset_of (ft, prog, ?j, p - 1, mem))"
thus "(r \<and>* st ?j \<and>* tm p v2 \<and>* ps (p - 1) \<and>* sg {TC i ((L, ?j), L, ?j)})
(trset_of (ft, prog, ?j, p - 1, mem))"
by(simp add: sep_conj_ac)
qed
thus "\<exists>k. (r \<and>* st ?j \<and>* tm p v2 \<and>* ps (p - 1) \<and>* sg {TC i ((L, ?j), L, ?j)})
(trset_of (tm.run (Suc k) (ft, prog, cs, i', mem)))"
apply (rule_tac x = 0 in exI)
by auto
qed
qed
qed
lemma hoare_move_left_gen[step]:
assumes "p = q"
shows "\<lbrace>st i ** ps p ** tm q v2\<rbrace>
i:[move_left]:j
\<lbrace>st j ** ps (p - 1) ** tm q v2\<rbrace>"
by (unfold assms, rule hoare_move_left)
definition "move_right = (TL exit . \<guillemotright>((R, exit), (R, exit)); TLabel exit)"
lemma hoare_move_right:
"\<lbrace>st i ** ps p ** tm p v1 \<rbrace>
i:[move_right]:j
\<lbrace>st j ** ps (p + 1) ** tm p v1 \<rbrace>"
proof(unfold move_right_def, intro t_hoare_local, rule t_hoare_label_last, simp+)
fix l
show "\<lbrace>st i \<and>* ps p \<and>* tm p v1\<rbrace> i :[ \<guillemotright> ((R, l), R, l) ]: l
\<lbrace>st l \<and>* ps (p + 1) \<and>* tm p v1\<rbrace>"
proof(unfold tassemble_to.simps, simp only:sep_conj_cond,
intro tm.code_condI, simp add: sep_conj_ac)
let ?j = "Suc i"
show "\<lbrace>ps p \<and>* st i \<and>* tm p v1\<rbrace> sg {TC i ((R, ?j), R, ?j)}
\<lbrace>st ?j \<and>* tm p v1 \<and>* ps (p + 1)\<rbrace>"
proof(unfold tassemble_to.simps tm.Hoare_gen_def sep_conj_ac, clarify)
fix ft prog cs i' mem r
assume h: "(r \<and>* ps p \<and>* st i \<and>* tm p v1 \<and>* sg {TC i ((R, ?j), R, ?j)})
(trset_of (ft, prog, cs, i', mem))"
from h have "prog i = Some ((R, ?j), R, ?j)"
apply(rule_tac r = "r \<and>* ps p \<and>* tm p v1" in codeD)
by(simp add: sep_conj_ac)
from h and this have stp:
"tm.run 1 (ft, prog, cs, i', mem) = (ft, prog, ?j, i'+ 1, mem)" (is "?x = ?y")
apply(sep_frule psD)
apply(sep_frule stD)
apply(sep_frule memD, simp)
apply(unfold tm.run_def, case_tac v1, auto)
done
from h have "i' = p"
by(sep_drule psD, simp)
with h
have "(r \<and>* st ?j \<and>* tm p v1 \<and>* ps (p + 1) \<and>*
sg {TC i ((R, ?j), R, ?j)}) (trset_of ?x)"
apply(unfold stp)
apply(sep_drule pos_upd, sep_drule st_upd, simp)
proof -
assume "(st ?j \<and>* ps (p + 1) \<and>* r \<and>* tm p v1 \<and>* sg {TC i ((R, ?j), R, ?j)})
(trset_of (ft, prog, ?j, p + 1, mem))"
thus "(r \<and>* st ?j \<and>* tm p v1 \<and>* ps (p + 1) \<and>* sg {TC i ((R, ?j), R, ?j)})
(trset_of (ft, prog, ?j, p + 1, mem))"
by (simp add: sep_conj_ac)
qed
thus "\<exists>k. (r \<and>* st ?j \<and>* tm p v1 \<and>* ps (p + 1) \<and>* sg {TC i ((R, ?j), R, ?j)})
(trset_of (tm.run (Suc k) (ft, prog, cs, i', mem)))"
apply (rule_tac x = 0 in exI)
by auto
qed
qed
qed
lemma hoare_move_right_gen[step]:
assumes "p = q"
shows "\<lbrace>st i ** ps p ** tm q v1 \<rbrace>
i:[move_right]:j
\<lbrace>st j ** ps (p + 1) ** tm q v1 \<rbrace>"
by (unfold assms, rule hoare_move_right)
definition "if_one e = (TL exit . \<guillemotright>((W0, exit), (W1, e)); TLabel exit)"
lemma hoare_if_one_true:
"\<lbrace>st i ** ps p ** one p\<rbrace>
i:[if_one e]:j
\<lbrace>st e ** ps p ** one p\<rbrace>"
proof(unfold if_one_def, intro t_hoare_local, rule t_hoare_label_last, simp+)
fix l
show " \<lbrace>st i \<and>* ps p \<and>* one p\<rbrace> i :[ \<guillemotright> ((W0, l), W1, e) ]: l \<lbrace>st e \<and>* ps p \<and>* one p\<rbrace>"
proof(unfold tassemble_to.simps, simp only:sep_conj_cond,
intro tm.code_condI, simp add: sep_conj_ac)
let ?j = "Suc i"
show "\<lbrace>one p \<and>* ps p \<and>* st i\<rbrace> sg {TC i ((W0, ?j), W1, e)} \<lbrace>one p \<and>* ps p \<and>* st e\<rbrace>"
proof(unfold tassemble_to.simps tm.Hoare_gen_def sep_conj_ac, clarify)
fix ft prog cs pc mem r
assume h: "(r \<and>* one p \<and>* ps p \<and>* st i \<and>* sg {TC i ((W0, ?j), W1, e)})
(trset_of (ft, prog, cs, pc, mem))"
from h have k1: "prog i = Some ((W0, ?j), W1, e)"
apply(rule_tac r = "r \<and>* one p \<and>* ps p" in codeD)
by(simp add: sep_conj_ac)
from h have k2: "pc = p"
by(sep_drule psD, simp)
from h and this have k3: "mem pc = Some Oc"
apply(unfold one_def)
by(sep_drule memD, simp)
from h k1 k2 k3 have stp:
"tm.run 1 (ft, prog, cs, pc, mem) = (ft, prog, e, pc, mem)" (is "?x = ?y")
apply(sep_drule stD)
by(unfold tm.run_def, auto)
from h k2
have "(r \<and>* one p \<and>* ps p \<and>* st e \<and>* sg {TC i ((W0, ?j), W1, e)}) (trset_of ?x)"
apply(unfold stp)
by(sep_drule st_upd, simp add: sep_conj_ac)
thus "\<exists>k.(r \<and>* one p \<and>* ps p \<and>* st e \<and>* sg {TC i ((W0, ?j), W1, e)})
(trset_of (tm.run (Suc k) (ft, prog, cs, pc, mem)))"
apply (rule_tac x = 0 in exI)
by auto
qed
qed
qed
text {*
The following problematic lemma is not provable now
lemma hoare_self: "\<lbrace>p\<rbrace> i :[ap]: j \<lbrace>p\<rbrace>"
apply(simp add: tm.Hoare_gen_def, clarify)
apply(rule_tac x = 0 in exI, simp add: tm.run_def)
done
*}
lemma hoare_if_one_true_gen[step]:
assumes "p = q"
shows
"\<lbrace>st i ** ps p ** one q\<rbrace>
i:[if_one e]:j
\<lbrace>st e ** ps p ** one q\<rbrace>"
by (unfold assms, rule hoare_if_one_true)
lemma hoare_if_one_true1:
"\<lbrace>st i ** ps p ** one p\<rbrace>
i:[(if_one e; c)]:j
\<lbrace>st e ** ps p ** one p\<rbrace>"
proof(unfold tassemble_to.simps, rule tm.code_exI,
simp add: sep_conj_ac tm.Hoare_gen_def, clarify)
fix j' ft prog cs pos mem r
assume h: "(r \<and>* one p \<and>* ps p \<and>* st i \<and>* j' :[ c ]: j \<and>* i :[ if_one e ]: j')
(trset_of (ft, prog, cs, pos, mem))"
from tm.frame_rule[OF hoare_if_one_true]
have "\<And> r. \<lbrace>st i \<and>* ps p \<and>* one p \<and>* r\<rbrace> i :[ if_one e ]: j' \<lbrace>st e \<and>* ps p \<and>* one p \<and>* r\<rbrace>"
by(simp add: sep_conj_ac)
from this[unfolded tm.Hoare_gen_def tassemble_to.simps, rule_format, of "j' :[ c ]: j"] h
have "\<exists> k. (r \<and>* one p \<and>* ps p \<and>* st e \<and>* i :[ if_one e ]: j' \<and>* j' :[ c ]: j)
(trset_of (tm.run (Suc k) (ft, prog, cs, pos, mem)))"
by(auto simp: sep_conj_ac)
thus "\<exists>k. (r \<and>* one p \<and>* ps p \<and>* st e \<and>* j' :[ c ]: j \<and>* i :[ if_one e ]: j')
(trset_of (tm.run (Suc k) (ft, prog, cs, pos, mem)))"
by(simp add: sep_conj_ac)
qed
lemma hoare_if_one_true1_gen[step]:
assumes "p = q"
shows
"\<lbrace>st i ** ps p ** one q\<rbrace>
i:[(if_one e; c)]:j
\<lbrace>st e ** ps p ** one q\<rbrace>"
by (unfold assms, rule hoare_if_one_true1)
lemma hoare_if_one_false:
"\<lbrace>st i ** ps p ** zero p\<rbrace>
i:[if_one e]:j
\<lbrace>st j ** ps p ** zero p\<rbrace>"
proof(unfold if_one_def, intro t_hoare_local, rule t_hoare_label_last, simp+)
show "\<lbrace>st i \<and>* ps p \<and>* zero p\<rbrace> i :[ (\<guillemotright> ((W0, j), W1, e)) ]: j
\<lbrace>st j \<and>* ps p \<and>* zero p\<rbrace>"
proof(unfold tassemble_to.simps, simp only:sep_conj_cond,
intro tm.code_condI, simp add: sep_conj_ac)
let ?j = "Suc i"
show "\<lbrace>ps p \<and>* st i \<and>* zero p\<rbrace> sg {TC i ((W0, ?j), W1, e)} \<lbrace>ps p \<and>* zero p \<and>* st ?j \<rbrace>"
proof(unfold tassemble_to.simps tm.Hoare_gen_def sep_conj_ac, clarify)
fix ft prog cs pc mem r
assume h: "(r \<and>* ps p \<and>* st i \<and>* zero p \<and>* sg {TC i ((W0, ?j), W1, e)})
(trset_of (ft, prog, cs, pc, mem))"
from h have k1: "prog i = Some ((W0, ?j), W1, e)"
apply(rule_tac r = "r \<and>* zero p \<and>* ps p" in codeD)
by(simp add: sep_conj_ac)
from h have k2: "pc = p"
by(sep_drule psD, simp)
from h and this have k3: "mem pc = Some Bk"
apply(unfold zero_def)
by(sep_drule memD, simp)
from h k1 k2 k3 have stp:
"tm.run 1 (ft, prog, cs, pc, mem) = (ft, prog, ?j, pc, mem)" (is "?x = ?y")
apply(sep_drule stD)
by(unfold tm.run_def, auto)
from h k2
have "(r \<and>* zero p \<and>* ps p \<and>* st ?j \<and>* sg {TC i ((W0, ?j), W1, e)}) (trset_of ?x)"
apply (unfold stp)
by (sep_drule st_upd[where i''="?j"], auto simp:sep_conj_ac)
thus "\<exists>k. (r \<and>* ps p \<and>* zero p \<and>* st ?j \<and>* sg {TC i ((W0, ?j), W1, e)})
(trset_of (tm.run (Suc k) (ft, prog, cs, pc, mem)))"
by(auto simp: sep_conj_ac)
qed
qed
qed
lemma hoare_if_one_false_gen[step]:
assumes "p = q"
shows "\<lbrace>st i ** ps p ** zero q\<rbrace>
i:[if_one e]:j
\<lbrace>st j ** ps p ** zero q\<rbrace>"
by (unfold assms, rule hoare_if_one_false)
definition "if_zero e = (TL exit . \<guillemotright>((W0, e), (W1, exit)); TLabel exit)"
lemma hoare_if_zero_true:
"\<lbrace>st i ** ps p ** zero p\<rbrace>
i:[if_zero e]:j
\<lbrace>st e ** ps p ** zero p\<rbrace>"
proof(unfold if_zero_def, intro t_hoare_local, rule t_hoare_label_last, simp+)
fix l
show "\<lbrace>st i \<and>* ps p \<and>* zero p\<rbrace> i :[ \<guillemotright> ((W0, e), W1, l) ]: l \<lbrace>st e \<and>* ps p \<and>* zero p\<rbrace>"
proof(unfold tassemble_to.simps, simp only:sep_conj_cond,
intro tm.code_condI, simp add: sep_conj_ac)
let ?j = "Suc i"
show "\<lbrace>ps p \<and>* st i \<and>* zero p\<rbrace> sg {TC i ((W0, e), W1, ?j)} \<lbrace>ps p \<and>* st e \<and>* zero p\<rbrace>"
proof(unfold tassemble_to.simps tm.Hoare_gen_def sep_conj_ac, clarify)
fix ft prog cs pc mem r
assume h: "(r \<and>* ps p \<and>* st i \<and>* zero p \<and>* sg {TC i ((W0, e), W1, ?j)})
(trset_of (ft, prog, cs, pc, mem))"
from h have k1: "prog i = Some ((W0, e), W1, ?j)"
apply(rule_tac r = "r \<and>* zero p \<and>* ps p" in codeD)
by(simp add: sep_conj_ac)
from h have k2: "pc = p"
by(sep_drule psD, simp)
from h and this have k3: "mem pc = Some Bk"
apply(unfold zero_def)
by(sep_drule memD, simp)
from h k1 k2 k3 have stp:
"tm.run 1 (ft, prog, cs, pc, mem) = (ft, prog, e, pc, mem)" (is "?x = ?y")
apply(sep_drule stD)
by(unfold tm.run_def, auto)
from h k2
have "(r \<and>* zero p \<and>* ps p \<and>* st e \<and>* sg {TC i ((W0, e), W1, ?j)}) (trset_of ?x)"
apply(unfold stp)
by(sep_drule st_upd, simp add: sep_conj_ac)
thus "\<exists>k. (r \<and>* ps p \<and>* st e \<and>* zero p \<and>* sg {TC i ((W0, e), W1, ?j)})
(trset_of (tm.run (Suc k) (ft, prog, cs, pc, mem)))"
by(auto simp: sep_conj_ac)
qed
qed
qed
lemma hoare_if_zero_true_gen[step]:
assumes "p = q"
shows
"\<lbrace>st i ** ps p ** zero q\<rbrace>
i:[if_zero e]:j
\<lbrace>st e ** ps p ** zero q\<rbrace>"
by (unfold assms, rule hoare_if_zero_true)
lemma hoare_if_zero_true1:
"\<lbrace>st i ** ps p ** zero p\<rbrace>
i:[(if_zero e; c)]:j
\<lbrace>st e ** ps p ** zero p\<rbrace>"
proof(unfold tassemble_to.simps, rule tm.code_exI, simp add: sep_conj_ac
tm.Hoare_gen_def, clarify)
fix j' ft prog cs pos mem r
assume h: "(r \<and>* ps p \<and>* st i \<and>* zero p \<and>* j' :[ c ]: j \<and>* i :[ if_zero e ]: j')
(trset_of (ft, prog, cs, pos, mem))"
from tm.frame_rule[OF hoare_if_zero_true]
have "\<And> r. \<lbrace>st i \<and>* ps p \<and>* zero p \<and>* r\<rbrace> i :[ if_zero e ]: j' \<lbrace>st e \<and>* ps p \<and>* zero p \<and>* r\<rbrace>"
by(simp add: sep_conj_ac)
from this[unfolded tm.Hoare_gen_def tassemble_to.simps, rule_format, of "j' :[ c ]: j"] h
have "\<exists> k. (r \<and>* zero p \<and>* ps p \<and>* st e \<and>* i :[ if_zero e ]: j' \<and>* j' :[ c ]: j)
(trset_of (tm.run (Suc k) (ft, prog, cs, pos, mem)))"
by(auto simp: sep_conj_ac)
thus "\<exists>k. (r \<and>* ps p \<and>* st e \<and>* zero p \<and>* j' :[ c ]: j \<and>* i :[ if_zero e ]: j')
(trset_of (tm.run (Suc k) (ft, prog, cs, pos, mem)))"
by(simp add: sep_conj_ac)
qed
lemma hoare_if_zero_true1_gen[step]:
assumes "p = q"
shows
"\<lbrace>st i ** ps p ** zero q\<rbrace>
i:[(if_zero e; c)]:j
\<lbrace>st e ** ps p ** zero q\<rbrace>"
by (unfold assms, rule hoare_if_zero_true1)
lemma hoare_if_zero_false:
"\<lbrace>st i ** ps p ** tm p Oc\<rbrace>
i:[if_zero e]:j
\<lbrace>st j ** ps p ** tm p Oc\<rbrace>"
proof(unfold if_zero_def, intro t_hoare_local, rule t_hoare_label_last, simp, simp)
fix l
show "\<lbrace>st i \<and>* ps p \<and>* tm p Oc\<rbrace> i :[ \<guillemotright> ((W0, e), W1, l) ]: l
\<lbrace>st l \<and>* ps p \<and>* tm p Oc\<rbrace>"
proof(unfold tassemble_to.simps, simp only:sep_conj_cond,
intro tm.code_condI, simp add: sep_conj_ac)
let ?j = "Suc i"
show "\<lbrace>ps p \<and>* st i \<and>* tm p Oc\<rbrace> sg {TC i ((W0, e), W1, ?j)}
\<lbrace>ps p \<and>* st ?j \<and>* tm p Oc\<rbrace>"
proof(unfold tassemble_to.simps tm.Hoare_gen_def sep_conj_ac, clarify)
fix ft prog cs pc mem r
assume h: "(r \<and>* ps p \<and>* st i \<and>* tm p Oc \<and>* sg {TC i ((W0, e), W1, ?j)})
(trset_of (ft, prog, cs, pc, mem))"
from h have k1: "prog i = Some ((W0, e), W1, ?j)"
apply(rule_tac r = "r \<and>* tm p Oc \<and>* ps p" in codeD)
by(simp add: sep_conj_ac)
from h have k2: "pc = p"
by(sep_drule psD, simp)
from h and this have k3: "mem pc = Some Oc"
by(sep_drule memD, simp)
from h k1 k2 k3 have stp:
"tm.run 1 (ft, prog, cs, pc, mem) = (ft, prog, ?j, pc, mem)" (is "?x = ?y")
apply(sep_drule stD)
by(unfold tm.run_def, auto)
from h k2
have "(r \<and>* tm p Oc \<and>* ps p \<and>* st ?j \<and>* sg {TC i ((W0, e), W1, ?j)}) (trset_of ?x)"
apply(unfold stp)
by(sep_drule st_upd, simp add: sep_conj_ac)
thus "\<exists>k. (r \<and>* ps p \<and>* st ?j \<and>* tm p Oc \<and>* sg {TC i ((W0, e), W1, ?j)})
(trset_of (tm.run (Suc k) (ft, prog, cs, pc, mem)))"
by(auto simp: sep_conj_ac)
qed
qed
qed
lemma hoare_if_zero_false_gen[step]:
assumes "p = q"
shows
"\<lbrace>st i ** ps p ** tm q Oc\<rbrace>
i:[if_zero e]:j
\<lbrace>st j ** ps p ** tm q Oc\<rbrace>"
by (unfold assms, rule hoare_if_zero_false)
definition "jmp e = \<guillemotright>((W0, e), (W1, e))"
lemma hoare_jmp:
"\<lbrace>st i \<and>* ps p \<and>* tm p v\<rbrace> i:[jmp e]:j \<lbrace>st e \<and>* ps p \<and>* tm p v\<rbrace>"
proof(unfold jmp_def tm.Hoare_gen_def tassemble_to.simps sep_conj_ac, clarify)
fix ft prog cs pos mem r
assume h: "(r \<and>* ps p \<and>* st i \<and>* tm p v \<and>* <(j = i + 1)> \<and>* sg {TC i ((W0, e), W1, e)})
(trset_of (ft, prog, cs, pos, mem))"
from h have k1: "prog i = Some ((W0, e), W1, e)"
apply(rule_tac r = "r \<and>* <(j = i + 1)> \<and>* tm p v \<and>* ps p" in codeD)
by(simp add: sep_conj_ac)
from h have k2: "p = pos"
by(sep_drule psD, simp)
from h k2 have k3: "mem pos = Some v"
by(sep_drule memD, simp)
from h k1 k2 k3 have
stp: "tm.run 1 (ft, prog, cs, pos, mem) = (ft, prog, e, pos, mem)" (is "?x = ?y")
apply(sep_drule stD)
by(unfold tm.run_def, cases "mem pos", simp, cases v, auto)
from h k2
have "(r \<and>* ps p \<and>* st e \<and>* tm p v \<and>* <(j = i + 1)> \<and>*
sg {TC i ((W0, e), W1, e)}) (trset_of ?x)"
apply(unfold stp)
by(sep_drule st_upd, simp add: sep_conj_ac)
thus "\<exists> k. (r \<and>* ps p \<and>* st e \<and>* tm p v \<and>* <(j = i + 1)> \<and>* sg {TC i ((W0, e), W1, e)})
(trset_of (tm.run (Suc k) (ft, prog, cs, pos, mem)))"
apply (rule_tac x = 0 in exI)
by auto
qed
lemma hoare_jmp_gen[step]:
assumes "p = q"
shows "\<lbrace>st i \<and>* ps p \<and>* tm q v\<rbrace> i:[jmp e]:j \<lbrace>st e \<and>* ps p \<and>* tm q v\<rbrace>"
by (unfold assms, rule hoare_jmp)
lemma hoare_jmp1:
"\<lbrace>st i \<and>* ps p \<and>* tm p v\<rbrace>
i:[(jmp e; c)]:j
\<lbrace>st e \<and>* ps p \<and>* tm p v\<rbrace>"
proof(unfold tassemble_to.simps, rule tm.code_exI, simp
add: sep_conj_ac tm.Hoare_gen_def, clarify)
fix j' ft prog cs pos mem r
assume h: "(r \<and>* ps p \<and>* st i \<and>* tm p v \<and>* j' :[ c ]: j \<and>* i :[ jmp e ]: j')
(trset_of (ft, prog, cs, pos, mem))"
from tm.frame_rule[OF hoare_jmp]
have "\<And> r. \<lbrace>st i \<and>* ps p \<and>* tm p v \<and>* r\<rbrace> i :[ jmp e ]: j' \<lbrace>st e \<and>* ps p \<and>* tm p v \<and>* r\<rbrace>"
by(simp add: sep_conj_ac)
from this[unfolded tm.Hoare_gen_def tassemble_to.simps, rule_format, of "j' :[ c ]: j"] h
have "\<exists> k. (r \<and>* tm p v \<and>* ps p \<and>* st e \<and>* i :[ jmp e ]: j' \<and>* j' :[ c ]: j)
(trset_of (tm.run (Suc k) (ft, prog, cs, pos, mem)))"
by(auto simp: sep_conj_ac)
thus "\<exists>k. (r \<and>* ps p \<and>* st e \<and>* tm p v \<and>* j' :[ c ]: j \<and>* i :[ jmp e ]: j')
(trset_of (tm.run (Suc k) (ft, prog, cs, pos, mem)))"
by(simp add: sep_conj_ac)
qed
lemma hoare_jmp1_gen[step]:
assumes "p = q"
shows "\<lbrace>st i \<and>* ps p \<and>* tm q v\<rbrace>
i:[(jmp e; c)]:j
\<lbrace>st e \<and>* ps p \<and>* tm q v\<rbrace>"
by (unfold assms, rule hoare_jmp1)
lemma condI:
assumes h1: b
and h2: "b \<Longrightarrow> p s"
shows "(<b> \<and>* p) s"
by (metis (full_types) cond_true_eq1 h1 h2)
lemma condE:
assumes "(<b> \<and>* p) s"
obtains "b" and "p s"
proof(atomize_elim)
from condD[OF assms]
show "b \<and> p s" .
qed
section {* Tactics *}
ML {*
val trace_step = Attrib.setup_config_bool @{binding trace_step} (K false)
val trace_fwd = Attrib.setup_config_bool @{binding trace_fwd} (K false)
*}
ML {*
val tracing = (fn ctxt => fn str =>
if (Config.get ctxt trace_step) then tracing str else ())
fun not_pred p = fn s => not (p s)
fun break_sep_conj (Const (@{const_name sep_conj},_) $ t1 $ t2 $ _) =
(break_sep_conj t1) @ (break_sep_conj t2)
| break_sep_conj (Const (@{const_name sep_conj},_) $ t1 $ t2) =
(break_sep_conj t1) @ (break_sep_conj t2)
(* dig through eta exanded terms: *)
| break_sep_conj (Abs (_, _, t $ Bound 0)) = break_sep_conj t
| break_sep_conj t = [t];
val empty_env = (Vartab.empty, Vartab.empty)
fun match_env ctxt pat trm env =
Pattern.match (ctxt |> Proof_Context.theory_of) (pat, trm) env
fun match ctxt pat trm = match_env ctxt pat trm empty_env;
val inst = Envir.subst_term;
fun term_of_thm thm = thm |> prop_of |> HOLogic.dest_Trueprop
fun get_cmd ctxt code =
let val pat = term_of @{cpat "_:[(?cmd)]:_"}
val pat1 = term_of @{cpat "?cmd::tpg"}
val env = match ctxt pat code
in inst env pat1 end
fun is_seq_term (Const (@{const_name TSeq}, _) $ _ $ _) = true
| is_seq_term _ = false
fun get_hcmd (Const (@{const_name TSeq}, _) $ hcmd $ _) = hcmd
| get_hcmd hcmd = hcmd
fun last [a] = a |
last (a::b) = last b
fun but_last [a] = [] |
but_last (a::b) = a::(but_last b)
fun foldr f [] = (fn x => x) |
foldr f (x :: xs) = (f x) o (foldr f xs)
fun concat [] = [] |
concat (x :: xs) = x @ concat xs
fun match_any ctxt pats tm =
fold
(fn pat => fn b => (b orelse Pattern.matches
(ctxt |> Proof_Context.theory_of) (pat, tm)))
pats false
fun is_ps_term (Const (@{const_name ps}, _) $ _) = true
| is_ps_term _ = false
fun string_of_term ctxt t = t |> Syntax.pretty_term ctxt |> Pretty.str_of
fun string_of_cterm ctxt ct = ct |> term_of |> string_of_term ctxt
fun pterm ctxt t =
t |> string_of_term ctxt |> tracing ctxt
fun pcterm ctxt ct = ct |> string_of_cterm ctxt |> tracing ctxt
fun string_for_term ctxt t =
Print_Mode.setmp (filter (curry (op =) Symbol.xsymbolsN)
(print_mode_value ())) (Syntax.string_of_term ctxt) t
|> String.translate (fn c => if Char.isPrint c then str c else "")
|> Sledgehammer_Util.simplify_spaces
fun string_for_cterm ctxt ct = ct |> term_of |> string_for_term ctxt
fun attemp tac = fn i => fn st => (tac i st) handle exn => Seq.empty
fun try_tac tac = fn i => fn st => (tac i st) handle exn => (Seq.single st)
(* aux end *)
*}
ML {* (* Functions specific to Hoare triples *)
fun get_pre ctxt t =
let val pat = term_of @{cpat "\<lbrace>?P\<rbrace> ?c \<lbrace>?Q\<rbrace>"}
val env = match ctxt pat t
in inst env (term_of @{cpat "?P::tresource set \<Rightarrow> bool"}) end
fun can_process ctxt t = ((get_pre ctxt t; true) handle _ => false)
fun get_post ctxt t =
let val pat = term_of @{cpat "\<lbrace>?P\<rbrace> ?c \<lbrace>?Q\<rbrace>"}
val env = match ctxt pat t
in inst env (term_of @{cpat "?Q::tresource set \<Rightarrow> bool"}) end;
fun get_mid ctxt t =
let val pat = term_of @{cpat "\<lbrace>?P\<rbrace> ?c \<lbrace>?Q\<rbrace>"}
val env = match ctxt pat t
in inst env (term_of @{cpat "?c::tresource set \<Rightarrow> bool"}) end;
fun is_pc_term (Const (@{const_name st}, _) $ _) = true
| is_pc_term _ = false
fun mk_pc_term x =
Const (@{const_name st}, @{typ "nat \<Rightarrow> tresource set \<Rightarrow> bool"}) $ Free (x, @{typ "nat"})
val sconj_term = term_of @{cterm "sep_conj::tassert \<Rightarrow> tassert \<Rightarrow> tassert"}
fun mk_ps_term x =
Const (@{const_name ps}, @{typ "int \<Rightarrow> tresource set \<Rightarrow> bool"}) $ Free (x, @{typ "int"})
fun atomic tac = ((SOLVED' tac) ORELSE' (K all_tac))
fun map_simpset f = Context.proof_map (Simplifier.map_ss f)
fun pure_sep_conj_ac_tac ctxt =
(auto_tac (map_simpset (fn ss => ss addsimps @{thms sep_conj_ac}) ctxt)
|> SELECT_GOAL)
fun potential_facts ctxt prop = Facts.could_unify (Proof_Context.facts_of ctxt)
((Term.strip_all_body prop) |> Logic.strip_imp_concl);
fun some_fact_tac ctxt = SUBGOAL (fn (goal, i) =>
(Method.insert_tac (potential_facts ctxt goal) i) THEN
(pure_sep_conj_ac_tac ctxt i));
fun sep_conj_ac_tac ctxt =
(SOLVED' (auto_tac (ctxt |> map_simpset (fn ss => ss addsimps @{thms sep_conj_ac}))
|> SELECT_GOAL)) ORELSE' (atomic (some_fact_tac ctxt))
*}
ML {*
type HoareTriple = {
binding: binding,
can_process: Proof.context -> term -> bool,
get_pre: Proof.context -> term -> term,
get_mid: Proof.context -> term -> term,
get_post: Proof.context -> term -> term,
is_pc_term: term -> bool,
mk_pc_term: string -> term,
sconj_term: term,
sep_conj_ac_tac: Proof.context -> int -> tactic,
hoare_seq1: thm,
hoare_seq2: thm,
pre_stren: thm,
post_weaken: thm,
frame_rule: thm
}
val tm_triple = {binding = @{binding "tm_triple"},
can_process = can_process,
get_pre = get_pre,
get_mid = get_mid,
get_post = get_post,
is_pc_term = is_pc_term,
mk_pc_term = mk_pc_term,
sconj_term = sconj_term,
sep_conj_ac_tac = sep_conj_ac_tac,
hoare_seq1 = @{thm t_hoare_seq1},
hoare_seq2 = @{thm t_hoare_seq2},
pre_stren = @{thm tm.pre_stren},
post_weaken = @{thm tm.post_weaken},
frame_rule = @{thm tm.frame_rule}
}:HoareTriple
*}
ML {*
val _ = data_slot "HoareTriples" "HoareTriple list" "[]"
*}
ML {*
val _ = HoareTriples_store [tm_triple]
*}
ML {* (* aux1 functions *)
fun focus_params t ctxt =
let
val (xs, Ts) =
split_list (Term.variant_frees t (Term.strip_all_vars t)); (*as they are printed :-*)
(* val (xs', ctxt') = variant_fixes xs ctxt; *)
(* val ps = xs' ~~ Ts; *)
val ps = xs ~~ Ts
val (_, ctxt'') = ctxt |> Variable.add_fixes xs
in ((xs, ps), ctxt'') end
fun focus_concl ctxt t =
let
val ((xs, ps), ctxt') = focus_params t ctxt
val t' = Term.subst_bounds (rev (map Free ps), Term.strip_all_body t);
in (t' |> Logic.strip_imp_concl, ctxt') end
fun get_concl ctxt (i, state) =
nth (Thm.prems_of state) (i - 1)
|> focus_concl ctxt |> (fn (x, _) => x |> HOLogic.dest_Trueprop)
(* aux1 end *)
*}
ML {*
fun indexing xs = upto (0, length xs - 1) ~~ xs
fun select_idxs idxs ps =
map_index (fn (i, e) => if (member (op =) idxs i) then [e] else []) ps |> flat
fun select_out_idxs idxs ps =
map_index (fn (i, e) => if (member (op =) idxs i) then [] else [e]) ps |> flat
fun match_pres ctxt mf env ps qs =
let fun sel_match mf env [] qs = [(env, [])]
| sel_match mf env (p::ps) qs =
let val pm = map (fn (i, q) => [(i,
let val _ = tracing ctxt "Matching:"
val _ = [p, q] |>
(pretty_terms ctxt) |> Pretty.str_of |> tracing ctxt
val r = mf p q env
in r end)]
handle _ => (
let val _ = tracing ctxt "Failed matching:"
val _ = [p, q] |>
(pretty_terms ctxt) |> Pretty.str_of |> tracing ctxt
in [] end)) qs |> flat
val r = pm |> map (fn (i, env') =>
let val qs' = filter_out (fn (j, q) => j = i) qs
in sel_match mf env' ps qs' |>
map (fn (env'', idxs) => (env'', i::idxs)) end)
|> flat
in r end
in sel_match mf env ps (indexing qs) end
fun provable tac ctxt goal =
let
val _ = tracing ctxt "Provable trying to prove:"
val _ = [goal] |> (pretty_terms ctxt) |> Pretty.str_of |> tracing ctxt
in
(Goal.prove ctxt [] [] goal (fn {context, ...} => tac context 1); true)
handle exn => false
end
fun make_sense tac ctxt thm_assms env =
thm_assms |> map (inst env) |> forall (provable tac ctxt)
*}
ML {*
fun triple_for ctxt goal =
filter (fn trpl => (#can_process trpl) ctxt goal) (HoareTriples.get (Proof_Context.theory_of ctxt)) |> hd
fun step_terms_for thm goal ctxt =
let
val _ = tracing ctxt "This is the new version of step_terms_for!"
val _ = tracing ctxt "Tring to find triple processor: TP"
val TP = triple_for ctxt goal
val _ = #binding TP |> Binding.name_of |> tracing ctxt
fun mk_sep_conj tms = foldr (fn tm => fn rtm =>
((#sconj_term TP)$tm$rtm)) (but_last tms) (last tms)
val thm_concl = thm |> prop_of
|> Logic.strip_imp_concl |> HOLogic.dest_Trueprop
val thm_assms = thm |> prop_of
|> Logic.strip_imp_prems
val cmd_pat = thm_concl |> #get_mid TP ctxt |> get_cmd ctxt
val cmd = goal |> #get_mid TP ctxt |> get_cmd ctxt
val _ = tracing ctxt "matching command ... "
val _ = tracing ctxt "cmd_pat = "
val _ = pterm ctxt cmd_pat
val (hcmd, env1, is_last) = (cmd, match ctxt cmd_pat cmd, true)
handle exn => (cmd |> get_hcmd, match ctxt cmd_pat (cmd |> get_hcmd), false)
val _ = tracing ctxt "hcmd ="
val _ = pterm ctxt hcmd
val _ = tracing ctxt "match command succeed! "
val _ = tracing ctxt "pres ="
val pres = goal |> #get_pre TP ctxt |> break_sep_conj
val _ = pres |> (pretty_terms ctxt) |> Pretty.str_of |> tracing ctxt
val _ = tracing ctxt "pre_pats ="
val pre_pats = thm_concl |> #get_pre TP ctxt |> inst env1 |> break_sep_conj
val _ = pre_pats |> (pretty_terms ctxt) |> Pretty.str_of |> tracing ctxt
val _ = tracing ctxt "post_pats ="
val post_pats = thm_concl |> #get_post TP ctxt |> inst env1 |> break_sep_conj
val _ = post_pats |> (pretty_terms ctxt) |> Pretty.str_of |> tracing ctxt
val _ = tracing ctxt "Calculating sols"
val sols = match_pres ctxt (match_env ctxt) env1 pre_pats pres
val _ = tracing ctxt "End calculating sols, sols ="
val _ = tracing ctxt (@{make_string} sols)
val _ = tracing ctxt "Calulating env2 and idxs"
val (env2, idxs) = filter (fn (env, idxs) => make_sense (#sep_conj_ac_tac TP)
ctxt thm_assms env) sols |> hd
val _ = tracing ctxt "End calculating env2 and idxs"
val _ = tracing ctxt "mterms ="
val mterms = select_idxs idxs pres |> map (inst env2)
val _ = mterms |> (pretty_terms ctxt) |> Pretty.str_of |> tracing ctxt
val _ = tracing ctxt "nmterms = "
val nmterms = select_out_idxs idxs pres |> map (inst env2)
val _ = nmterms |> (pretty_terms ctxt) |> Pretty.str_of |> tracing ctxt
val pre_cond = pre_pats |> map (inst env2) |> mk_sep_conj
val post_cond = post_pats |> map (inst env2) |> mk_sep_conj
val post_cond_npc =
post_cond |> break_sep_conj |> filter (not_pred (#is_pc_term TP))
|> (fn x => x @ nmterms) |> mk_sep_conj |> cterm_of (Proof_Context.theory_of ctxt)
fun mk_frame cond rest =
if rest = [] then cond else ((#sconj_term TP)$ cond) $ (mk_sep_conj rest)
val pre_cond_frame = mk_frame pre_cond nmterms |> cterm_of (Proof_Context.theory_of ctxt)
fun post_cond_frame j' = post_cond |> break_sep_conj |> filter (not_pred (#is_pc_term TP))
|> (fn x => [#mk_pc_term TP j']@x) |> mk_sep_conj
|> (fn x => mk_frame x nmterms)
|> cterm_of (Proof_Context.theory_of ctxt)
val need_frame = (nmterms <> [])
in
(post_cond_npc,
pre_cond_frame,
post_cond_frame, need_frame, is_last)
end
*}
ML {*
fun step_tac ctxt thm i state =
let
val _ = tracing ctxt "This is the new version of step_tac"
val (goal, ctxt) = nth (Thm.prems_of state) (i - 1)
|> focus_concl ctxt
|> (apfst HOLogic.dest_Trueprop)
val _ = tracing ctxt "step_tac: goal = "
val _ = goal |> pterm ctxt
val _ = tracing ctxt "Start to calculate intermediate terms ... "
val (post_cond_npc, pre_cond_frame, post_cond_frame, need_frame, is_last)
= step_terms_for thm goal ctxt
val _ = tracing ctxt "Tring to find triple processor: TP"
val TP = triple_for ctxt goal
val _ = #binding TP |> Binding.name_of |> tracing ctxt
fun mk_sep_conj tms = foldr (fn tm => fn rtm =>
((#sconj_term TP)$tm$rtm)) (but_last tms) (last tms)
val _ = tracing ctxt "Calculate intermediate terms finished! "
val post_cond_npc_str = post_cond_npc |> string_for_cterm ctxt
val pre_cond_frame_str = pre_cond_frame |> string_for_cterm ctxt
val _ = tracing ctxt "step_tac: post_cond_npc = "
val _ = post_cond_npc |> pcterm ctxt
val _ = tracing ctxt "step_tac: pre_cond_frame = "
val _ = pre_cond_frame |> pcterm ctxt
fun tac1 i state =
if is_last then (K all_tac) i state else
res_inst_tac ctxt [(("q", 0), post_cond_npc_str)]
(#hoare_seq1 TP) i state
fun tac2 i state = res_inst_tac ctxt [(("p", 0), pre_cond_frame_str)]
(#pre_stren TP) i state
fun foc_tac post_cond_frame ctxt i state =
let
val goal = get_concl ctxt (i, state)
val pc_term = goal |> #get_post TP ctxt |> break_sep_conj
|> filter (#is_pc_term TP) |> hd
val (_$Free(j', _)) = pc_term
val psd = post_cond_frame j'
val str_psd = psd |> string_for_cterm ctxt
val _ = tracing ctxt "foc_tac: psd = "
val _ = psd |> pcterm ctxt
in
res_inst_tac ctxt [(("q", 0), str_psd)]
(#post_weaken TP) i state
end
val frame_tac = if need_frame then (rtac (#frame_rule TP)) else (K all_tac)
val print_tac = if (Config.get ctxt trace_step) then Tactical.print_tac else (K all_tac)
val tac = (tac1 THEN' (K (print_tac "tac1 success"))) THEN'
(tac2 THEN' (K (print_tac "tac2 success"))) THEN'
((foc_tac post_cond_frame ctxt) THEN' (K (print_tac "foc_tac success"))) THEN'
(frame_tac THEN' (K (print_tac "frame_tac success"))) THEN'
(((rtac thm) THEN_ALL_NEW (#sep_conj_ac_tac TP ctxt)) THEN' (K (print_tac "rtac thm success"))) THEN'
(K (ALLGOALS (atomic (#sep_conj_ac_tac TP ctxt)))) THEN'
(* (#sep_conj_ac_tac TP ctxt) THEN' (#sep_conj_ac_tac TP ctxt) THEN' *)
(K prune_params_tac)
in
tac i state
end
fun unfold_cell_tac ctxt = (Local_Defs.unfold_tac ctxt @{thms one_def zero_def})
fun fold_cell_tac ctxt = (Local_Defs.fold_tac ctxt @{thms one_def zero_def})
*}
ML {*
fun sg_step_tac thms ctxt =
let val sg_step_tac' = (map (fn thm => attemp (step_tac ctxt thm)) thms)
(* @ [attemp (goto_tac ctxt)] *)
|> FIRST'
val sg_step_tac'' = (K (unfold_cell_tac ctxt)) THEN' sg_step_tac' THEN' (K (fold_cell_tac ctxt))
in
sg_step_tac' ORELSE' sg_step_tac''
end
fun steps_tac thms ctxt i = REPEAT (sg_step_tac thms ctxt i) THEN (prune_params_tac)
*}
method_setup hstep = {*
Attrib.thms >> (fn thms => fn ctxt =>
(SIMPLE_METHOD' (fn i =>
sg_step_tac (thms@(StepRules.get ctxt)) ctxt i)))
*}
"One step symbolic execution using step theorems."
method_setup hsteps = {*
Attrib.thms >> (fn thms => fn ctxt =>
(SIMPLE_METHOD' (fn i =>
steps_tac (thms@(StepRules.get ctxt)) ctxt i)))
*}
"Sequential symbolic execution using step theorems."
ML {*
fun goto_tac ctxt thm i state =
let
val (goal, ctxt) = nth (Thm.prems_of state) (i - 1)
|> focus_concl ctxt |> (apfst HOLogic.dest_Trueprop)
val _ = tracing ctxt "goto_tac: goal = "
val _ = goal |> string_of_term ctxt |> tracing ctxt
val (post_cond_npc, pre_cond_frame, post_cond_frame, need_frame, is_last)
= step_terms_for thm goal ctxt
val _ = tracing ctxt "Tring to find triple processor: TP"
val TP = triple_for ctxt goal
val _ = #binding TP |> Binding.name_of |> tracing ctxt
val _ = tracing ctxt "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"
val post_cond_npc_str = post_cond_npc |> string_for_cterm ctxt
val pre_cond_frame_str = pre_cond_frame |> string_for_cterm ctxt
val _ = tracing ctxt "goto_tac: post_cond_npc = "
val _ = post_cond_npc_str |> tracing ctxt
val _ = tracing ctxt "goto_tac: pre_cond_frame = "
val _ = pre_cond_frame_str |> tracing ctxt
fun tac1 i state =
if is_last then (K all_tac) i state else
res_inst_tac ctxt []
(#hoare_seq2 TP) i state
fun tac2 i state = res_inst_tac ctxt [(("p", 0), pre_cond_frame_str)]
(#pre_stren TP) i state
fun foc_tac post_cond_frame ctxt i state =
let
val goal = get_concl ctxt (i, state)
val pc_term = goal |> #get_post TP ctxt |> break_sep_conj
|> filter (#is_pc_term TP) |> hd
val (_$Free(j', _)) = pc_term
val psd = post_cond_frame j'
val str_psd = psd |> string_for_cterm ctxt
val _ = tracing ctxt "goto_tac: psd = "
val _ = str_psd |> tracing ctxt
in
res_inst_tac ctxt [(("q", 0), str_psd)]
(#post_weaken TP) i state
end
val frame_tac = if need_frame then (rtac (#frame_rule TP)) else (K all_tac)
val _ = tracing ctxt "goto_tac: starting to apply tacs"
val print_tac = if (Config.get ctxt trace_step) then Tactical.print_tac else (K all_tac)
val tac = (tac1 THEN' (K (print_tac "tac1 success"))) THEN'
(tac2 THEN' (K (print_tac "tac2 success"))) THEN'
((foc_tac post_cond_frame ctxt) THEN' (K (print_tac "foc_tac success"))) THEN'
(frame_tac THEN' (K (print_tac "frame_tac success"))) THEN'
((((rtac thm) THEN_ALL_NEW (#sep_conj_ac_tac TP ctxt))) THEN'
(K (print_tac "rtac success"))
) THEN'
(K (ALLGOALS (atomic (#sep_conj_ac_tac TP ctxt)))) THEN'
(K prune_params_tac)
in
tac i state
end
*}
ML {*
fun sg_goto_tac thms ctxt =
let val sg_goto_tac' = (map (fn thm => attemp (goto_tac ctxt thm)) thms)
|> FIRST'
val sg_goto_tac'' = (K (unfold_cell_tac ctxt)) THEN' sg_goto_tac' THEN' (K (fold_cell_tac ctxt))
in
sg_goto_tac' ORELSE' sg_goto_tac''
end
fun gotos_tac thms ctxt i = REPEAT (sg_goto_tac thms ctxt i) THEN (prune_params_tac)
*}
method_setup hgoto = {*
Attrib.thms >> (fn thms => fn ctxt =>
(SIMPLE_METHOD' (fn i =>
sg_goto_tac (thms@(StepRules.get ctxt)) ctxt i)))
*}
"One step symbolic execution using goto theorems."
subsection {* Tactic for forward reasoning *}
ML {*
fun mk_msel_rule ctxt conclusion idx term =
let
val cjt_count = term |> break_sep_conj |> length
fun variants nctxt names = fold_map Name.variant names nctxt;
val (state, nctxt0) = Name.variant "s" (Variable.names_of ctxt);
fun sep_conj_prop cjts =
FunApp.fun_app_free
(FunApp.fun_app_foldr SepConj.sep_conj_term cjts) state
|> HOLogic.mk_Trueprop;
(* concatenate string and string of an int *)
fun conc_str_int str int = str ^ Int.toString int;
(* make the conjunct names *)
val (cjts, _) = ListExtra.range 1 cjt_count
|> map (conc_str_int "a") |> variants nctxt0;
fun skel_sep_conj names (Const (@{const_name sep_conj}, _) $ t1 $ t2 $ y) =
(let val nm1 = take (length (break_sep_conj t1)) names
val nm2 = drop (length (break_sep_conj t1)) names
val t1' = skel_sep_conj nm1 t1
val t2' = skel_sep_conj nm2 t2
in (SepConj.sep_conj_term $ t1' $ t2' $ y) end)
| skel_sep_conj names (Const (@{const_name sep_conj}, _) $ t1 $ t2) =
(let val nm1 = take (length (break_sep_conj t1)) names
val nm2 = drop (length (break_sep_conj t1)) names
val t1' = skel_sep_conj nm1 t1
val t2' = skel_sep_conj nm2 t2
in (SepConj.sep_conj_term $ t1' $ t2') end)
| skel_sep_conj names (Abs (x, y, t $ Bound 0)) =
let val t' = (skel_sep_conj names t)
val ty' = t' |> type_of |> domain_type
in (Abs (x, ty', (t' $ Bound 0))) end
| skel_sep_conj names t = Free (hd names, SepConj.sep_conj_term |> type_of |> domain_type);
val _ = tracing ctxt "xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx"
val oskel = skel_sep_conj cjts term;
val _ = tracing ctxt "yyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyyy"
val ttt = oskel |> type_of
val _ = tracing ctxt "zzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz"
val orig = FunApp.fun_app_free oskel state |> HOLogic.mk_Trueprop
val _ = tracing ctxt "uuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuuu"
val is_selected = member (fn (x, y) => x = y) idx
val all_idx = ListExtra.range 0 cjt_count
val selected_idx = idx
val unselected_idx = filter_out is_selected all_idx
val selected = map (nth cjts) selected_idx
val unselected = map (nth cjts) unselected_idx
fun fun_app_foldr f [a,b] = FunApp.fun_app_free (FunApp.fun_app_free f a) b
| fun_app_foldr f [a] = Free (a, SepConj.sep_conj_term |> type_of |> domain_type)
| fun_app_foldr f (x::xs) = (FunApp.fun_app_free f x) $ (fun_app_foldr f xs)
| fun_app_foldr _ _ = raise Fail "fun_app_foldr";
val reordered_skel =
if unselected = [] then (fun_app_foldr SepConj.sep_conj_term selected)
else (SepConj.sep_conj_term $ (fun_app_foldr SepConj.sep_conj_term selected)
$ (fun_app_foldr SepConj.sep_conj_term unselected))
val reordered = FunApp.fun_app_free reordered_skel state |> HOLogic.mk_Trueprop
val goal = Logic.mk_implies
(if conclusion then (orig, reordered) else (reordered, orig));
val rule =
Goal.prove ctxt [] [] goal (fn _ =>
auto_tac (ctxt |> map_simpset (fn ss => ss addsimps @{thms sep_conj_ac})))
|> Drule.export_without_context
in
rule
end
*}
lemma fwd_rule:
assumes "\<And> s . U s \<longrightarrow> V s"
shows "(U ** RR) s \<Longrightarrow> (V ** RR) s"
by (metis assms sep_globalise)
ML {*
fun sg_sg_fwd_tac ctxt thm pos i state =
let
val tracing = (fn str =>
if (Config.get ctxt trace_fwd) then Output.tracing str else ())
fun pterm t =
t |> string_of_term ctxt |> tracing
fun pcterm ct = ct |> string_of_cterm ctxt |> tracing
fun atm thm =
let
(* val thm = thm |> Drule.forall_intr_vars *)
val res = thm |> cprop_of |> Object_Logic.atomize
val res' = Raw_Simplifier.rewrite_rule [res] thm
in res' end
fun find_idx ctxt pats terms =
let val result =
map (fn pat => (find_index (fn trm => ((match ctxt pat trm; true)
handle _ => false)) terms)) pats
in (assert_all (fn x => x >= 0) result (K "match of precondition failed"));
result
end
val goal = nth (Drule.cprems_of state) (i - 1) |> term_of
val _ = tracing "goal = "
val _ = goal |> pterm
val ctxt_orig = ctxt
val ((ps, goal), ctxt) = Variable.focus goal ctxt_orig
val prems = goal |> Logic.strip_imp_prems
val cprem = nth prems (pos - 1)
val (_ $ (the_prem $ _)) = cprem
val cjts = the_prem |> break_sep_conj
val thm_prems = thm |> cprems_of |> hd |> Thm.dest_arg |> Thm.dest_fun
val thm_assms = thm |> cprems_of |> tl |> map term_of
val thm_cjts = thm_prems |> term_of |> break_sep_conj
val thm_trm = thm |> prop_of
val _ = tracing "cjts = "
val _ = cjts |> map pterm
val _ = tracing "thm_cjts = "
val _ = thm_cjts |> map pterm
val _ = tracing "Calculating sols"
val sols = match_pres ctxt (match_env ctxt) empty_env thm_cjts cjts
val _ = tracing "End calculating sols, sols ="
val _ = tracing (@{make_string} sols)
val _ = tracing "Calulating env2 and idxs"
val (env2, idx) = filter (fn (env, idxs) => make_sense sep_conj_ac_tac ctxt thm_assms env) sols |> hd
val ([thm'_trm], ctxt') = thm_trm |> inst env2 |> single
|> (fn trms => Variable.import_terms true trms ctxt)
val thm'_prem = Logic.strip_imp_prems thm'_trm |> hd
val thm'_concl = Logic.strip_imp_concl thm'_trm
val thm'_prem = (Goal.prove ctxt' [] [thm'_prem] thm'_concl
(fn {context, prems = [prem]} =>
(rtac (prem RS thm) THEN_ALL_NEW (sep_conj_ac_tac ctxt)) 1))
val [thm'] = Variable.export ctxt' ctxt_orig [thm'_prem]
val trans_rule =
mk_msel_rule ctxt true idx the_prem
val _ = tracing "trans_rule = "
val _ = trans_rule |> cprop_of |> pcterm
val app_rule =
if (length cjts = length thm_cjts) then thm' else
((thm' |> atm) RS @{thm fwd_rule})
val _ = tracing "app_rule = "
val _ = app_rule |> cprop_of |> pcterm
val print_tac = if (Config.get ctxt trace_fwd) then Tactical.print_tac else (K all_tac)
val the_tac = (dtac trans_rule THEN' (K (print_tac "dtac1 success"))) THEN'
((dtac app_rule THEN' (K (print_tac "dtac2 success"))))
in
(the_tac i state) handle _ => no_tac state
end
*}
ML {*
fun sg_fwd_tac ctxt thm i state =
let
val goal = nth (Drule.cprems_of state) (i - 1)
val prems = goal |> term_of |> Term.strip_all_body |> Logic.strip_imp_prems
val posx = ListExtra.range 1 (length prems)
in
((map (fn pos => attemp (sg_sg_fwd_tac ctxt thm pos)) posx) |> FIRST') i state
end
fun fwd_tac ctxt thms i state =
((map (fn thm => sg_fwd_tac ctxt thm) thms) |> FIRST') i state
*}
method_setup fwd = {*
Attrib.thms >> (fn thms => fn ctxt =>
(SIMPLE_METHOD' (fn i =>
fwd_tac ctxt (thms@(FwdRules.get ctxt)) i)))
*}
"Forward derivation of separation implication"
text {* Testing the fwd tactic *}
lemma ones_abs:
assumes "(ones u v \<and>* ones w x) s" "w = v + 1"
shows "ones u x s"
using assms(1) unfolding assms(2)
proof(induct u v arbitrary: x s rule:ones_induct)
case (Base i j x s)
thus ?case by (auto elim!:condE)
next
case (Step i j x s)
hence h: "\<And> x s. (ones (i + 1) j \<and>* ones (j + 1) x) s \<longrightarrow> ones (i + 1) x s"
by metis
hence "(ones (i + 1) x \<and>* one i) s"
by (rule fwd_rule, insert Step(3), auto simp:sep_conj_ac)
thus ?case
by (smt condD ones.simps sep_conj_commute)
qed
lemma one_abs: "(one m) s \<Longrightarrow> (ones m m) s"
by (smt cond_true_eq2 ones.simps)
lemma ones_reps_abs:
assumes "ones m n s"
"m \<le> n"
shows "(reps m n [nat (n - m)]) s"
using assms
by simp
lemma reps_reps'_abs:
assumes "(reps m n xs \<and>* zero u) s" "u = n + 1" "xs \<noteq> []"
shows "(reps' m u xs) s"
unfolding assms using assms
by (unfold reps'_def, simp)
lemma reps'_abs:
assumes "(reps' m n xs \<and>* reps' u v ys) s" "u = n + 1"
shows "(reps' m v (xs @ ys)) s"
apply (unfold reps'_append, rule_tac x = u in EXS_intro)
by (insert assms, simp)
lemmas abs_ones = one_abs ones_abs
lemmas abs_reps' = ones_reps_abs reps_reps'_abs reps'_abs
section {* Modular TM programming and verification *}
definition "right_until_zero =
(TL start exit.
TLabel start;
if_zero exit;
move_right;
jmp start;
TLabel exit
)"
lemma ones_false [simp]: "j < i - 1 \<Longrightarrow> (ones i j) = sep_false"
by (simp add:pasrt_def)
lemma hoare_right_until_zero:
"\<lbrace>st i ** ps u ** ones u (v - 1) ** zero v \<rbrace>
i:[right_until_zero]:j
\<lbrace>st j ** ps v ** ones u (v - 1) ** zero v \<rbrace>"
proof(unfold right_until_zero_def,
intro t_hoare_local t_hoare_label, clarify,
rule t_hoare_label_last, simp, simp)
fix la
let ?body = "i :[ (if_zero la ; move_right ; jmp i) ]: la"
let ?j = la
show "\<lbrace>st i \<and>* ps u \<and>* ones u (v - 1) \<and>* zero v\<rbrace> ?body
\<lbrace>st ?j \<and>* ps v \<and>* ones u (v - 1) \<and>* zero v\<rbrace>" (is "?P u (v - 1) (ones u (v - 1))")
proof(induct "u" "v - 1" rule:ones_induct)
case (Base k)
moreover have "\<lbrace>st i \<and>* ps v \<and>* zero v\<rbrace> ?body
\<lbrace>st ?j \<and>* ps v \<and>* zero v\<rbrace>" by hsteps
ultimately show ?case by (auto intro!:tm.pre_condI simp:sep_conj_cond)
next
case (Step k)
moreover have "\<lbrace>st i \<and>* ps k \<and>* (one k \<and>* ones (k + 1) (v - 1)) \<and>* zero v\<rbrace>
i :[ (if_zero ?j ; move_right ; jmp i) ]: ?j
\<lbrace>st ?j \<and>* ps v \<and>* (one k \<and>* ones (k + 1) (v - 1)) \<and>* zero v\<rbrace>"
proof -
have s1: "\<lbrace>st i \<and>* ps k \<and>* (one k \<and>* ones (k + 1) (v - 1)) \<and>* zero v\<rbrace>
?body
\<lbrace>st i \<and>* ps (k + 1) \<and>* one k \<and>* ones (k + 1) (v - 1) \<and>* zero v\<rbrace>"
proof(cases "k + 1 \<ge> v")
case True
with Step(1) have "v = k + 1" by arith
thus ?thesis
apply(simp add: one_def)
by hsteps
next
case False
hence eq_ones: "ones (k + 1) (v - 1) =
(one (k + 1) \<and>* ones ((k + 1) + 1) (v - 1))"
by simp
show ?thesis
apply(simp only: eq_ones)
by hsteps
qed
note Step(2)[step]
have s2: "\<lbrace>st i \<and>* ps (k + 1) \<and>* one k \<and>* ones (k + 1) (v - 1) \<and>* zero v\<rbrace>
?body
\<lbrace>st ?j \<and>* ps v \<and>* one k \<and>* ones (k + 1) (v - 1) \<and>* zero v\<rbrace>"
by hsteps
from tm.sequencing [OF s1 s2, step]
show ?thesis
by (auto simp:sep_conj_ac)
qed
ultimately show ?case by simp
qed
qed
lemma hoare_right_until_zero_gen[step]:
assumes "u = v" "w = x - 1"
shows "\<lbrace>st i ** ps u ** ones v w ** zero x \<rbrace>
i:[right_until_zero]:j
\<lbrace>st j ** ps x ** ones v w ** zero x \<rbrace>"
by (unfold assms, rule hoare_right_until_zero)
definition "left_until_zero =
(TL start exit.
TLabel start;
if_zero exit;
move_left;
jmp start;
TLabel exit
)"
lemma hoare_left_until_zero:
"\<lbrace>st i ** ps v ** zero u ** ones (u + 1) v \<rbrace>
i:[left_until_zero]:j
\<lbrace>st j ** ps u ** zero u ** ones (u + 1) v \<rbrace>"
proof(unfold left_until_zero_def,
intro t_hoare_local t_hoare_label, clarify,
rule t_hoare_label_last, simp+)
fix la
let ?body = "i :[ (if_zero la ; move_left ; jmp i) ]: la"
let ?j = la
show "\<lbrace>st i \<and>* ps v \<and>* zero u \<and>* ones (u + 1) v\<rbrace> ?body
\<lbrace>st ?j \<and>* ps u \<and>* zero u \<and>* ones (u + 1) v\<rbrace>"
proof(induct "u+1" v rule:ones_rev_induct)
case (Base k)
thus ?case
by (simp add:sep_conj_cond, intro tm.pre_condI, simp, hstep)
next
case (Step k)
have "\<lbrace>st i \<and>* ps k \<and>* zero u \<and>* ones (u + 1) (k - 1) \<and>* one k\<rbrace>
?body
\<lbrace>st ?j \<and>* ps u \<and>* zero u \<and>* ones (u + 1) (k - 1) \<and>* one k\<rbrace>"
proof(rule tm.sequencing[where q =
"st i \<and>* ps (k - 1) \<and>* zero u \<and>* ones (u + 1) (k - 1) \<and>* one k"])
show "\<lbrace>st i \<and>* ps k \<and>* zero u \<and>* ones (u + 1) (k - 1) \<and>* one k\<rbrace>
?body
\<lbrace>st i \<and>* ps (k - 1) \<and>* zero u \<and>* ones (u + 1) (k - 1) \<and>* one k\<rbrace>"
proof(induct "u + 1" "k - 1" rule:ones_rev_induct)
case Base with Step(1) have "k = u + 1" by arith
thus ?thesis
by (simp, hsteps)
next
case Step
show ?thesis
apply (unfold ones_rev[OF Step(1)], simp)
apply (unfold one_def)
by hsteps
qed
next
note Step(2) [step]
show "\<lbrace>st i \<and>* ps (k - 1) \<and>* zero u \<and>* ones (u + 1) (k - 1) \<and>* one k\<rbrace>
?body
\<lbrace>st ?j \<and>* ps u \<and>* zero u \<and>* ones (u + 1) (k - 1) \<and>* one k\<rbrace>" by hsteps
qed
thus ?case by (unfold ones_rev[OF Step(1)], simp)
qed
qed
lemma hoare_left_until_zero_gen[step]:
assumes "u = x" "w = v + 1"
shows "\<lbrace>st i ** ps u ** zero v ** ones w x \<rbrace>
i:[left_until_zero]:j
\<lbrace>st j ** ps v ** zero v ** ones w x \<rbrace>"
by (unfold assms, rule hoare_left_until_zero)
definition "right_until_one =
(TL start exit.
TLabel start;
if_one exit;
move_right;
jmp start;
TLabel exit
)"
lemma hoare_right_until_one:
"\<lbrace>st i ** ps u ** zeros u (v - 1) ** one v \<rbrace>
i:[right_until_one]:j
\<lbrace>st j ** ps v ** zeros u (v - 1) ** one v \<rbrace>"
proof(unfold right_until_one_def,
intro t_hoare_local t_hoare_label, clarify,
rule t_hoare_label_last, simp+)
fix la
let ?body = "i :[ (if_one la ; move_right ; jmp i) ]: la"
let ?j = la
show "\<lbrace>st i \<and>* ps u \<and>* zeros u (v - 1) \<and>* one v\<rbrace> ?body
\<lbrace>st ?j \<and>* ps v \<and>* zeros u (v - 1) \<and>* one v\<rbrace>"
proof(induct u "v - 1" rule:zeros_induct)
case (Base k)
thus ?case
by (simp add:sep_conj_cond, intro tm.pre_condI, simp, hsteps)
next
case (Step k)
have "\<lbrace>st i \<and>* ps k \<and>* zero k \<and>* zeros (k + 1) (v - 1) \<and>* one v\<rbrace>
?body
\<lbrace>st ?j \<and>* ps v \<and>* zero k \<and>* zeros (k + 1) (v - 1) \<and>* one v\<rbrace>"
proof(rule tm.sequencing[where q =
"st i \<and>* ps (k + 1) \<and>* zero k \<and>* zeros (k + 1) (v - 1) \<and>* one v"])
show "\<lbrace>st i \<and>* ps k \<and>* zero k \<and>* zeros (k + 1) (v - 1) \<and>* one v\<rbrace>
?body
\<lbrace>st i \<and>* ps (k + 1) \<and>* zero k \<and>* zeros (k + 1) (v - 1) \<and>* one v\<rbrace>"
proof(induct "k + 1" "v - 1" rule:zeros_induct)
case Base
with Step(1) have eq_v: "k + 1 = v" by arith
from Base show ?thesis
apply (simp add:sep_conj_cond, intro tm.pre_condI, simp)
apply (hstep, clarsimp)
by hsteps
next
case Step
thus ?thesis
by (simp, hsteps)
qed
next
note Step(2)[step]
show "\<lbrace>st i \<and>* ps (k + 1) \<and>* zero k \<and>* zeros (k + 1) (v - 1) \<and>* one v\<rbrace>
?body
\<lbrace>st ?j \<and>* ps v \<and>* zero k \<and>* zeros (k + 1) (v - 1) \<and>* one v\<rbrace>"
by hsteps
qed
thus ?case by (auto simp: sep_conj_ac Step(1))
qed
qed
lemma hoare_right_until_one_gen[step]:
assumes "u = v" "w = x - 1"
shows
"\<lbrace>st i ** ps u ** zeros v w ** one x \<rbrace>
i:[right_until_one]:j
\<lbrace>st j ** ps x ** zeros v w ** one x \<rbrace>"
by (unfold assms, rule hoare_right_until_one)
definition "left_until_one =
(TL start exit.
TLabel start;
if_one exit;
move_left;
jmp start;
TLabel exit
)"
lemma hoare_left_until_one:
"\<lbrace>st i ** ps v ** one u ** zeros (u + 1) v \<rbrace>
i:[left_until_one]:j
\<lbrace>st j ** ps u ** one u ** zeros (u + 1) v \<rbrace>"
proof(unfold left_until_one_def,
intro t_hoare_local t_hoare_label, clarify,
rule t_hoare_label_last, simp+)
fix la
let ?body = "i :[ (if_one la ; move_left ; jmp i) ]: la"
let ?j = la
show "\<lbrace>st i \<and>* ps v \<and>* one u \<and>* zeros (u + 1) v\<rbrace> ?body
\<lbrace>st ?j \<and>* ps u \<and>* one u \<and>* zeros (u + 1) v\<rbrace>"
proof(induct u v rule: ones'.induct)
fix ia ja
assume h: "\<not> ja < ia \<Longrightarrow>
\<lbrace>st i \<and>* ps (ja - 1) \<and>* one ia \<and>* zeros (ia + 1) (ja - 1)\<rbrace> ?body
\<lbrace>st ?j \<and>* ps ia \<and>* one ia \<and>* zeros (ia + 1) (ja - 1)\<rbrace>"
show "\<lbrace>st i \<and>* ps ja \<and>* one ia \<and>* zeros (ia + 1) ja\<rbrace> ?body
\<lbrace>st ?j \<and>* ps ia \<and>* one ia \<and>* zeros (ia + 1) ja\<rbrace>"
proof(cases "ja < ia")
case False
note lt = False
from h[OF this] have [step]:
"\<lbrace>st i \<and>* ps (ja - 1) \<and>* one ia \<and>* zeros (ia + 1) (ja - 1)\<rbrace> ?body
\<lbrace>st ?j \<and>* ps ia \<and>* one ia \<and>* zeros (ia + 1) (ja - 1)\<rbrace>" .
show ?thesis
proof(cases "ja = ia")
case True
moreover
have "\<lbrace>st i \<and>* ps ja \<and>* one ja\<rbrace> ?body \<lbrace>st ?j \<and>* ps ja \<and>* one ja\<rbrace>"
by hsteps
ultimately show ?thesis by auto
next
case False
with lt have k1: "ia < ja" by auto
from zeros_rev[of "ja" "ia + 1"] this
have eq_zeros: "zeros (ia + 1) ja = (zeros (ia + 1) (ja - 1) \<and>* zero ja)"
by simp
have s1: "\<lbrace>st i \<and>* ps ja \<and>* one ia \<and>* zeros (ia + 1) (ja - 1) \<and>* zero ja\<rbrace>
?body
\<lbrace>st i \<and>* ps (ja - 1) \<and>* one ia \<and>* zeros (ia + 1) (ja - 1) \<and>* zero ja\<rbrace>"
proof(cases "ia + 1 \<ge> ja")
case True
from k1 True have "ja = ia + 1" by arith
moreover have "\<lbrace>st i \<and>* ps (ia + 1) \<and>* one (ia + 1 - 1) \<and>* zero (ia + 1)\<rbrace>
i :[ (if_one ?j ; move_left ; jmp i) ]: ?j
\<lbrace>st i \<and>* ps (ia + 1 - 1) \<and>* one (ia + 1 - 1) \<and>* zero (ia + 1)\<rbrace>"
by (hsteps)
ultimately show ?thesis
by (simp)
next
case False
from zeros_rev[of "ja - 1" "ia + 1"] False
have k: "zeros (ia + 1) (ja - 1) =
(zeros (ia + 1) (ja - 1 - 1) \<and>* zero (ja - 1))"
by auto
show ?thesis
apply (unfold k, simp)
by hsteps
qed
have s2: "\<lbrace>st i \<and>* ps (ja - 1) \<and>* one ia \<and>* zeros (ia + 1) (ja - 1) \<and>* zero ja\<rbrace>
?body
\<lbrace>st ?j \<and>* ps ia \<and>* one ia \<and>* zeros (ia + 1) (ja - 1) \<and>* zero ja\<rbrace>"
by hsteps
from tm.sequencing[OF s1 s2, step]
show ?thesis
apply (unfold eq_zeros)
by hstep
qed (* ccc *)
next
case True
thus ?thesis by (auto intro:tm.hoare_sep_false)
qed
qed
qed
lemma hoare_left_until_one_gen[step]:
assumes "u = x" "w = v + 1"
shows "\<lbrace>st i ** ps u ** one v ** zeros w x \<rbrace>
i:[left_until_one]:j
\<lbrace>st j ** ps v ** one v ** zeros w x \<rbrace>"
by (unfold assms, rule hoare_left_until_one)
definition "left_until_double_zero =
(TL start exit.
TLabel start;
if_zero exit;
left_until_zero;
move_left;
if_one start;
TLabel exit)"
declare ones.simps[simp del]
lemma reps_simps3: "ks \<noteq> [] \<Longrightarrow>
reps i j (k # ks) = (ones i (i + int k) ** zero (i + int k + 1) ** reps (i + int k + 2) j ks)"
by(case_tac ks, simp, simp add: reps.simps)
lemma cond_eqI:
assumes h: "b \<Longrightarrow> r = s"
shows "(<b> ** r) = (<b> ** s)"
proof(cases b)
case True
from h[OF this] show ?thesis by simp
next
case False
thus ?thesis
by (unfold sep_conj_def set_ins_def pasrt_def, auto)
qed
lemma reps_rev: "ks \<noteq> []
\<Longrightarrow> reps i j (ks @ [k]) = (reps i (j - int (k + 1) - 1 ) ks \<and>*
zero (j - int (k + 1)) \<and>* ones (j - int k) j)"
proof(induct ks arbitrary: i j)
case Nil
thus ?case by simp
next
case (Cons a ks)
show ?case
proof(cases "ks = []")
case True
thus ?thesis
proof -
have eq_cond: "(j = i + int a + 2 + int k) = (-2 + (j - int k) = i + int a)" by auto
have "(<(-2 + (j - int k) = i + int a)> \<and>*
one i \<and>* ones (i + 1) (i + int a) \<and>*
zero (i + int a + 1) \<and>* one (i + int a + 2) \<and>* ones (3 + (i + int a)) (i + int a + 2 + int k))
=
(<(-2 + (j - int k) = i + int a)> \<and>* one i \<and>* ones (i + 1) (i + int a) \<and>*
zero (j - (1 + int k)) \<and>* one (j - int k) \<and>* ones (j - int k + 1) j)"
(is "(<?X> \<and>* ?L) = (<?X> \<and>* ?R)")
proof(rule cond_eqI)
assume h: "-2 + (j - int k) = i + int a"
hence eqs: "i + int a + 1 = j - (1 + int k)"
"i + int a + 2 = j - int k"
"3 + (i + int a) = j - int k + 1"
"(i + int a + 2 + int k) = j"
by auto
show "?L = ?R"
by (unfold eqs, auto simp:sep_conj_ac)
qed
with True
show ?thesis
apply (simp del:ones_simps reps.simps)
apply (simp add:sep_conj_cond eq_cond)
by (auto simp:sep_conj_ac)
qed
next
case False
from Cons(1)[OF False, of "i + int a + 2" j] this
show ?thesis
by(simp add: reps_simps3 sep_conj_ac)
qed
qed
lemma hoare_if_one_reps:
assumes nn: "ks \<noteq> []"
shows "\<lbrace>st i ** ps v ** reps u v ks\<rbrace>
i:[if_one e]:j
\<lbrace>st e ** ps v ** reps u v ks\<rbrace>"
proof(rule rev_exhaust[of ks])
assume "ks = []" with nn show ?thesis by simp
next
fix y ys
assume eq_ks: "ks = ys @ [y]"
show " \<lbrace>st i \<and>* ps v \<and>* reps u v ks\<rbrace> i :[ if_one e ]: j \<lbrace>st e \<and>* ps v \<and>* reps u v ks\<rbrace>"
proof(cases "ys = []")
case False
have "\<lbrace>st i \<and>* ps v \<and>* reps u v (ys @ [y])\<rbrace> i :[ if_one e ]: j \<lbrace>st e \<and>* ps v \<and>* reps u v (ys @ [y])\<rbrace>"
apply(unfold reps_rev[OF False], simp del:ones_simps add:ones_rev)
by hstep
thus ?thesis
by (simp add:eq_ks)
next
case True
with eq_ks
show ?thesis
apply (simp del:ones_simps add:ones_rev sep_conj_cond, intro tm.pre_condI, simp)
by hstep
qed
qed
lemma hoare_if_one_reps_gen[step]:
assumes nn: "ks \<noteq> []" "u = w"
shows "\<lbrace>st i ** ps u ** reps v w ks\<rbrace>
i:[if_one e]:j
\<lbrace>st e ** ps u ** reps v w ks\<rbrace>"
by (unfold `u = w`, rule hoare_if_one_reps[OF `ks \<noteq> []`])
lemma hoare_if_zero_ones_false[step]:
assumes "\<not> w < u" "v = w"
shows "\<lbrace>st i \<and>* ps v \<and>* ones u w\<rbrace>
i :[if_zero e]: j
\<lbrace>st j \<and>* ps v \<and>* ones u w\<rbrace>"
by (unfold `v = w` ones_rev[OF `\<not> w < u`], hstep)
lemma hoare_left_until_double_zero_nil[step]:
assumes "u = v"
shows "\<lbrace>st i ** ps u ** zero v\<rbrace>
i:[left_until_double_zero]:j
\<lbrace>st j ** ps u ** zero v\<rbrace>"
apply (unfold `u = v` left_until_double_zero_def,
intro t_hoare_local t_hoare_label, clarsimp,
rule t_hoare_label_last, simp+)
by (hsteps)
lemma hoare_if_zero_reps_false:
assumes nn: "ks \<noteq> []"
shows "\<lbrace>st i ** ps v ** reps u v ks\<rbrace>
i:[if_zero e]:j
\<lbrace>st j ** ps v ** reps u v ks\<rbrace>"
proof(rule rev_exhaust[of ks])
assume "ks = []" with nn show ?thesis by simp
next
fix y ys
assume eq_ks: "ks = ys @ [y]"
show " \<lbrace>st i \<and>* ps v \<and>* reps u v ks\<rbrace> i :[ if_zero e ]: j \<lbrace>st j \<and>* ps v \<and>* reps u v ks\<rbrace>"
proof(cases "ys = []")
case False
have "\<lbrace>st i \<and>* ps v \<and>* reps u v (ys @ [y])\<rbrace> i :[ if_zero e ]: j \<lbrace>st j \<and>* ps v \<and>* reps u v (ys @ [y])\<rbrace>"
apply(unfold reps_rev[OF False], simp del:ones_simps add:ones_rev)
by hstep
thus ?thesis
by (simp add:eq_ks)
next
case True
with eq_ks
show ?thesis
apply (simp del:ones_simps add:ones_rev sep_conj_cond, intro tm.pre_condI, simp)
by hstep
qed
qed
lemma hoare_if_zero_reps_false_gen[step]:
assumes "ks \<noteq> []" "u = w"
shows "\<lbrace>st i ** ps u ** reps v w ks\<rbrace>
i:[if_zero e]:j
\<lbrace>st j ** ps u ** reps v w ks\<rbrace>"
by (unfold `u = w`, rule hoare_if_zero_reps_false[OF `ks \<noteq> []`])
lemma hoare_if_zero_reps_false1:
assumes nn: "ks \<noteq> []"
shows "\<lbrace>st i ** ps u ** reps u v ks\<rbrace>
i:[if_zero e]:j
\<lbrace>st j ** ps u ** reps u v ks\<rbrace>"
proof -
from nn obtain y ys where eq_ys: "ks = y#ys"
by (metis neq_Nil_conv)
show ?thesis
apply (unfold eq_ys)
by (case_tac ys, (simp, hsteps)+)
qed
lemma hoare_if_zero_reps_false1_gen[step]:
assumes nn: "ks \<noteq> []"
and h: "u = w"
shows "\<lbrace>st i ** ps u ** reps w v ks\<rbrace>
i:[if_zero e]:j
\<lbrace>st j ** ps u ** reps w v ks\<rbrace>"
by (unfold h, rule hoare_if_zero_reps_false1[OF `ks \<noteq> []`])
lemma hoare_left_until_double_zero:
assumes h: "ks \<noteq> []"
shows "\<lbrace>st i ** ps v ** zero u ** zero (u + 1) ** reps (u+2) v ks\<rbrace>
i:[left_until_double_zero]:j
\<lbrace>st j ** ps u ** zero u ** zero (u + 1) ** reps (u+2) v ks\<rbrace>"
proof(unfold left_until_double_zero_def,
intro t_hoare_local t_hoare_label, clarsimp,
rule t_hoare_label_last, simp+)
fix la
let ?body = "i :[ (if_zero la ; left_until_zero ; move_left ; if_one i) ]: j"
let ?j = j
show "\<lbrace>st i \<and>* ps v \<and>* zero u \<and>* zero (u + 1) \<and>* reps (u + 2) v ks\<rbrace>
?body
\<lbrace>st ?j \<and>* ps u \<and>* zero u \<and>* zero (u + 1) \<and>* reps (u + 2) v ks\<rbrace>"
using h
proof(induct ks arbitrary: v rule:rev_induct)
case Nil
with h show ?case by auto
next
case (snoc k ks)
show ?case
proof(cases "ks = []")
case True
have eq_ones:
"ones (u + 2) (u + 2 + int k) = (ones (u + 2) (u + 1 + int k) \<and>* one (u + 2 + int k))"
by (smt ones_rev)
have eq_ones': "(one (u + 2) \<and>* ones (3 + u) (u + 2 + int k)) =
(one (u + 2 + int k) \<and>* ones (u + 2) (u + 1 + int k))"
by (smt eq_ones ones.simps sep.mult_commute)
thus ?thesis
apply (insert True, simp del:ones_simps add:sep_conj_cond)
apply (rule tm.pre_condI, simp del:ones_simps, unfold eq_ones)
apply hsteps
apply (rule_tac p = "st j' \<and>* ps (u + 2 + int k) \<and>* zero u \<and>*
zero (u + 1) \<and>* ones (u + 2) (u + 2 + int k)"
in tm.pre_stren)
by (hsteps)
next
case False
from False have spt: "splited (ks @ [k]) ks [k]" by (unfold splited_def, auto)
show ?thesis
apply (unfold reps_splited[OF spt], simp del:ones_simps add:sep_conj_cond)
apply (rule tm.pre_condI, simp del:ones_simps)
apply (rule_tac q = "st i \<and>*
ps (1 + (u + int (reps_len ks))) \<and>*
zero u \<and>*
zero (u + 1) \<and>*
reps (u + 2) (1 + (u + int (reps_len ks))) ks \<and>*
zero (u + 2 + int (reps_len ks)) \<and>*
ones (3 + (u + int (reps_len ks))) (3 + (u + int (reps_len ks)) + int k)" in
tm.sequencing)
apply hsteps[1]
by (hstep snoc(1))
qed
qed
qed
lemma hoare_left_until_double_zero_gen[step]:
assumes h1: "ks \<noteq> []"
and h: "u = y" "w = v + 1" "x = v + 2"
shows "\<lbrace>st i ** ps u ** zero v ** zero w ** reps x y ks\<rbrace>
i:[left_until_double_zero]:j
\<lbrace>st j ** ps v ** zero v ** zero w ** reps x y ks\<rbrace>"
by (unfold h, rule hoare_left_until_double_zero[OF h1])
lemma hoare_jmp_reps1:
assumes "ks \<noteq> []"
shows "\<lbrace> st i \<and>* ps u \<and>* reps u v ks\<rbrace>
i:[jmp e]:j
\<lbrace> st e \<and>* ps u \<and>* reps u v ks\<rbrace>"
proof -
from assms obtain k ks' where Cons:"ks = k#ks'"
by (metis neq_Nil_conv)
thus ?thesis
proof(cases "ks' = []")
case True with Cons
show ?thesis
apply(simp add:sep_conj_cond reps.simps, intro tm.pre_condI, simp add:ones_simps)
by (hgoto hoare_jmp_gen)
next
case False
show ?thesis
apply (unfold `ks = k#ks'` reps_simp3[OF False], simp add:ones_simps)
by (hgoto hoare_jmp[where p = u])
qed
qed
lemma hoare_jmp_reps1_gen[step]:
assumes "ks \<noteq> []" "u = v"
shows "\<lbrace> st i \<and>* ps u \<and>* reps v w ks\<rbrace>
i:[jmp e]:j
\<lbrace> st e \<and>* ps u \<and>* reps v w ks\<rbrace>"
by (unfold assms, rule hoare_jmp_reps1[OF `ks \<noteq> []`])
lemma hoare_jmp_reps:
"\<lbrace> st i \<and>* ps u \<and>* reps u v ks \<and>* tm (v + 1) x \<rbrace>
i:[(jmp e; c)]:j
\<lbrace> st e \<and>* ps u \<and>* reps u v ks \<and>* tm (v + 1) x \<rbrace>"
proof(cases "ks")
case Nil
thus ?thesis
by (simp add:sep_conj_cond, intro tm.pre_condI, simp, hsteps)
next
case (Cons k ks')
thus ?thesis
proof(cases "ks' = []")
case True with Cons
show ?thesis
apply(simp add:sep_conj_cond, intro tm.pre_condI, simp)
by (hgoto hoare_jmp[where p = u])
next
case False
show ?thesis
apply (unfold `ks = k#ks'` reps_simp3[OF False], simp)
by (hgoto hoare_jmp[where p = u])
qed
qed
definition "shift_right =
(TL start exit.
TLabel start;
if_zero exit;
write_zero;
move_right;
right_until_zero;
write_one;
move_right;
jmp start;
TLabel exit
)"
lemma hoare_shift_right_cons:
assumes h: "ks \<noteq> []"
shows "\<lbrace>st i \<and>* ps u ** reps u v ks \<and>* zero (v + 1) \<and>* zero (v + 2) \<rbrace>
i:[shift_right]:j
\<lbrace>st j ** ps (v + 2) ** zero u ** reps (u + 1) (v + 1) ks ** zero (v + 2) \<rbrace>"
proof(unfold shift_right_def, intro t_hoare_local t_hoare_label, clarify,
rule t_hoare_label_last, auto)
fix la
have eq_ones: "\<And> u k. (one (u + int k + 1) \<and>* ones (u + 1) (u + int k)) =
(one (u + 1) \<and>* ones (2 + u) (u + 1 + int k))"
by (smt cond_true_eq2 ones.simps ones_rev sep.mult_assoc sep.mult_commute
sep.mult_left_commute sep_conj_assoc sep_conj_commute
sep_conj_cond1 sep_conj_cond2 sep_conj_cond3 sep_conj_left_commute
sep_conj_trivial_strip2)
show "\<lbrace>st i \<and>* ps u \<and>* reps u v ks \<and>* zero (v + 1) \<and>* zero (v + 2)\<rbrace>
i :[ (if_zero la ;
write_zero ; move_right ; right_until_zero ; write_one ; move_right ; jmp i) ]: la
\<lbrace>st la \<and>* ps (v + 2) \<and>* zero u \<and>* reps (u + 1) (v + 1) ks \<and>* zero (v + 2)\<rbrace>"
using h
proof(induct ks arbitrary:i u v)
case (Cons k ks)
thus ?case
proof(cases "ks = []")
let ?j = la
case True
let ?body = "i :[ (if_zero ?j ;
write_zero ;
move_right ;
right_until_zero ;
write_one ; move_right ; jmp i) ]: ?j"
have first_interation:
"\<lbrace>st i \<and>* ps u \<and>* one u \<and>* ones (u + 1) (u + int k) \<and>* zero (u + int k + 1) \<and>*
zero (u + int k + 2)\<rbrace>
?body
\<lbrace>st i \<and>*
ps (u + int k + 2) \<and>*
one (u + int k + 1) \<and>* ones (u + 1) (u + int k) \<and>* zero u \<and>* zero (u + int k + 2)\<rbrace>"
apply (hsteps)
by (simp add:sep_conj_ac, sep_cancel+, smt)
hence "\<lbrace>st i \<and>* ps u \<and>* one u \<and>* ones (u + 1) (u + int k) \<and>* zero (u + int k + 1) \<and>*
zero (u + int k + 2)\<rbrace>
?body
\<lbrace>st ?j \<and>* ps (u + int k + 2) \<and>* zero u \<and>* one (u + 1) \<and>*
ones (2 + u) (u + 1 + int k) \<and>* zero (u + int k + 2)\<rbrace>"
proof(rule tm.sequencing)
show "\<lbrace>st i \<and>*
ps (u + int k + 2) \<and>*
one (u + int k + 1) \<and>* ones (u + 1) (u + int k) \<and>* zero u \<and>* zero (u + int k + 2)\<rbrace>
?body
\<lbrace>st ?j \<and>*
ps (u + int k + 2) \<and>*
zero u \<and>* one (u + 1) \<and>* ones (2 + u) (u + 1 + int k) \<and>* zero (u + int k + 2)\<rbrace>"
apply (hgoto hoare_if_zero_true_gen)
by (simp add:sep_conj_ac eq_ones)
qed
with True
show ?thesis
by (simp, simp only:sep_conj_cond, intro tm.pre_condI, auto simp:sep_conj_ac)
next
case False
let ?j = la
let ?body = "i :[ (if_zero ?j ;
write_zero ;
move_right ; right_until_zero ;
write_one ; move_right ; jmp i) ]: ?j"
have eq_ones':
"(one (u + int k + 1) \<and>*
ones (u + 1) (u + int k) \<and>*
zero u \<and>* reps (u + int k + 2) v ks \<and>* zero (v + 1) \<and>* zero (v + 2))
=
(zero u \<and>*
ones (u + 1) (u + int k) \<and>*
one (u + int k + 1) \<and>* reps (u + int k + 2) v ks \<and>* zero (v + 1) \<and>* zero (v + 2))"
by (simp add:eq_ones sep_conj_ac)
have "\<lbrace>st i \<and>* ps u \<and>* one u \<and>* ones (u + 1) (u + int k) \<and>* zero (u + int k + 1) \<and>*
reps (u + int k + 2) v ks \<and>* zero (v + 1) \<and>* zero (v + 2)\<rbrace>
?body
\<lbrace>st i \<and>* ps (u + int k + 2) \<and>* zero u \<and>* ones (u + 1) (u + int k) \<and>*
one (u + int k + 1) \<and>* reps (u + int k + 2) v ks \<and>* zero (v + 1) \<and>* zero (v + 2)\<rbrace>"
apply (hsteps)
by (auto simp:sep_conj_ac, sep_cancel+, smt)
hence "\<lbrace>st i \<and>* ps u \<and>* one u \<and>* ones (u + 1) (u + int k) \<and>* zero (u + int k + 1) \<and>*
reps (u + int k + 2) v ks \<and>* zero (v + 1) \<and>* zero (v + 2)\<rbrace>
?body
\<lbrace>st ?j \<and>* ps (v + 2) \<and>* zero u \<and>* one (u + 1) \<and>* ones (2 + u) (u + 1 + int k) \<and>*
zero (2 + (u + int k)) \<and>* reps (3 + (u + int k)) (v + 1) ks \<and>* zero (v + 2)\<rbrace>"
proof(rule tm.sequencing)
have eq_ones':
"\<And> u k. (one (u + int k + 1) \<and>* ones (u + 1) (u + int k) \<and>* zero (u + int k + 2)) =
(one (u + 1) \<and>* zero (2 + (u + int k)) \<and>* ones (2 + u) (u + 1 + int k))"
by (smt eq_ones sep.mult_assoc sep_conj_commute)
show "\<lbrace>st i \<and>* ps (u + int k + 2) \<and>* zero u \<and>*
ones (u + 1) (u + int k) \<and>* one (u + int k + 1) \<and>* reps (u + int k + 2) v ks \<and>*
zero (v + 1) \<and>* zero (v + 2)\<rbrace>
?body
\<lbrace>st ?j \<and>* ps (v + 2) \<and>* zero u \<and>* one (u + 1) \<and>* ones (2 + u) (u + 1 + int k) \<and>*
zero (2 + (u + int k)) \<and>* reps (3 + (u + int k)) (v + 1) ks \<and>* zero (v + 2)\<rbrace>"
apply (hsteps Cons.hyps)
by (simp add:sep_conj_ac eq_ones, sep_cancel+, smt)
qed
thus ?thesis
by (unfold reps_simp3[OF False], auto simp:sep_conj_ac)
qed
qed auto
qed
lemma hoare_shift_right_cons_gen[step]:
assumes h: "ks \<noteq> []"
and h1: "u = v" "x = w + 1" "y = w + 2"
shows "\<lbrace>st i \<and>* ps u ** reps v w ks \<and>* zero x \<and>* zero y \<rbrace>
i:[shift_right]:j
\<lbrace>st j ** ps y ** zero v ** reps (v + 1) x ks ** zero y\<rbrace>"
by (unfold h1, rule hoare_shift_right_cons[OF h])
lemma shift_right_nil [step]:
assumes "u = v"
shows
"\<lbrace> st i \<and>* ps u \<and>* zero v \<rbrace>
i:[shift_right]:j
\<lbrace> st j \<and>* ps u \<and>* zero v \<rbrace>"
by (unfold assms shift_right_def, intro t_hoare_local t_hoare_label, clarify,
rule t_hoare_label_last, simp+, hstep)
text {*
@{text "clear_until_zero"} is useful to implement @{text "drag"}.
*}
definition "clear_until_zero =
(TL start exit.
TLabel start;
if_zero exit;
write_zero;
move_right;
jmp start;
TLabel exit)"
lemma hoare_clear_until_zero[step]:
"\<lbrace>st i ** ps u ** ones u v ** zero (v + 1)\<rbrace>
i :[clear_until_zero]: j
\<lbrace>st j ** ps (v + 1) ** zeros u v ** zero (v + 1)\<rbrace> "
proof(unfold clear_until_zero_def, intro t_hoare_local, rule t_hoare_label,
rule t_hoare_label_last, simp+)
let ?body = "i :[ (if_zero j ; write_zero ; move_right ; jmp i) ]: j"
show "\<lbrace>st i \<and>* ps u \<and>* ones u v \<and>* zero (v + 1)\<rbrace> ?body
\<lbrace>st j \<and>* ps (v + 1) \<and>* zeros u v \<and>* zero (v + 1)\<rbrace>"
proof(induct u v rule: zeros.induct)
fix ia ja
assume h: "\<not> ja < ia \<Longrightarrow>
\<lbrace>st i \<and>* ps (ia + 1) \<and>* ones (ia + 1) ja \<and>* zero (ja + 1)\<rbrace> ?body
\<lbrace>st j \<and>* ps (ja + 1) \<and>* zeros (ia + 1) ja \<and>* zero (ja + 1)\<rbrace>"
show "\<lbrace>st i \<and>* ps ia \<and>* ones ia ja \<and>* zero (ja + 1)\<rbrace> ?body
\<lbrace>st j \<and>* ps (ja + 1) \<and>* zeros ia ja \<and>* zero (ja + 1)\<rbrace>"
proof(cases "ja < ia")
case True
thus ?thesis
by (simp add: ones.simps zeros.simps sep_conj_ac, simp only:sep_conj_cond,
intro tm.pre_condI, simp, hsteps)
next
case False
note h[OF False, step]
from False have ones_eq: "ones ia ja = (one ia \<and>* ones (ia + 1) ja)"
by(simp add: ones.simps)
from False have zeros_eq: "zeros ia ja = (zero ia \<and>* zeros (ia + 1) ja)"
by(simp add: zeros.simps)
have s1: "\<lbrace>st i \<and>* ps ia \<and>* one ia \<and>* ones (ia + 1) ja \<and>* zero (ja + 1)\<rbrace> ?body
\<lbrace>st i \<and>* ps (ia + 1) \<and>* zero ia \<and>* ones (ia + 1) ja \<and>* zero (ja + 1)\<rbrace>"
proof(cases "ja < ia + 1")
case True
from True False have "ja = ia" by auto
thus ?thesis
apply(simp add: ones.simps)
by (hsteps)
next
case False
from False have "ones (ia + 1) ja = (one (ia + 1) \<and>* ones (ia + 1 + 1) ja)"
by(simp add: ones.simps)
thus ?thesis
by (simp, hsteps)
qed
have s2: "\<lbrace>st i \<and>* ps (ia + 1) \<and>* zero ia \<and>* ones (ia + 1) ja \<and>* zero (ja + 1)\<rbrace>
?body
\<lbrace>st j \<and>* ps (ja + 1) \<and>* zero ia \<and>* zeros (ia + 1) ja \<and>* zero (ja + 1)\<rbrace>"
by hsteps
from tm.sequencing[OF s1 s2] have
"\<lbrace>st i \<and>* ps ia \<and>* one ia \<and>* ones (ia + 1) ja \<and>* zero (ja + 1)\<rbrace> ?body
\<lbrace>st j \<and>* ps (ja + 1) \<and>* zero ia \<and>* zeros (ia + 1) ja \<and>* zero (ja + 1)\<rbrace>" .
thus ?thesis
unfolding ones_eq zeros_eq by(simp add: sep_conj_ac)
qed
qed
qed
lemma hoare_clear_until_zero_gen[step]:
assumes "u = v" "x = w + 1"
shows "\<lbrace>st i ** ps u ** ones v w ** zero x\<rbrace>
i :[clear_until_zero]: j
\<lbrace>st j ** ps x ** zeros v w ** zero x\<rbrace>"
by (unfold assms, rule hoare_clear_until_zero)
definition "shift_left =
(TL start exit.
TLabel start;
if_zero exit;
move_left;
write_one;
right_until_zero;
move_left;
write_zero;
move_right;
move_right;
jmp start;
TLabel exit)
"
declare ones_simps[simp del]
lemma hoare_move_left_reps[step]:
assumes "ks \<noteq> []" "u = v"
shows
"\<lbrace>st i ** ps u ** reps v w ks\<rbrace>
i:[move_left]:j
\<lbrace>st j ** ps (u - 1) ** reps v w ks\<rbrace>"
proof -
from `ks \<noteq> []` obtain y ys where eq_ks: "ks = y#ys"
by (metis neq_Nil_conv)
show ?thesis
apply (unfold assms eq_ks)
apply (case_tac ys, simp)
my_block
have "(ones v (v + int y)) = (one v \<and>* ones (v + 1) (v + int y))"
by (smt ones_step_simp)
my_block_end
apply (unfold this, hsteps)
by (simp add:this, hsteps)
qed
lemma hoare_shift_left_cons:
assumes h: "ks \<noteq> []"
shows "\<lbrace>st i \<and>* ps u \<and>* tm (u - 1) x \<and>* reps u v ks \<and>* zero (v + 1) \<and>* zero (v + 2) \<rbrace>
i:[shift_left]:j
\<lbrace>st j \<and>* ps (v + 2) \<and>* reps (u - 1) (v - 1) ks \<and>* zero v \<and>* zero (v + 1) \<and>* zero (v + 2) \<rbrace>"
proof(unfold shift_left_def, intro t_hoare_local t_hoare_label, clarify,
rule t_hoare_label_last, simp+, clarify, prune)
show " \<lbrace>st i \<and>* ps u \<and>* tm (u - 1) x \<and>* reps u v ks \<and>* zero (v + 1) \<and>* zero (v + 2)\<rbrace>
i :[ (if_zero j ;
move_left ;
write_one ;
right_until_zero ;
move_left ; write_zero ;
move_right ; move_right ; jmp i) ]: j
\<lbrace>st j \<and>* ps (v + 2) \<and>* reps (u - 1) (v - 1) ks \<and>* zero v \<and>* zero (v + 1) \<and>* zero (v + 2)\<rbrace>"
using h
proof(induct ks arbitrary:i u v x)
case (Cons k ks)
thus ?case
proof(cases "ks = []")
let ?body = "i :[ (if_zero j ; move_left ; write_one ; right_until_zero ;
move_left ; write_zero ; move_right ; move_right ; jmp i) ]: j"
case True
have "\<lbrace>st i \<and>* ps u \<and>* tm (u - 1) x \<and>* (one u \<and>* ones (u + 1) (u + int k)) \<and>*
zero (u + int k + 1) \<and>* zero (u + int k + 2)\<rbrace>
?body
\<lbrace>st j \<and>* ps (u + int k + 2) \<and>* (one (u - 1) \<and>* ones u (u - 1 + int k)) \<and>*
zero (u + int k) \<and>* zero (u + int k + 1) \<and>* zero (u + int k + 2)\<rbrace>"
apply(rule tm.sequencing [where q = "st i \<and>* ps (u + int k + 2) \<and>*
(one (u - 1) \<and>* ones u (u - 1 + int k)) \<and>*
zero (u + int k) \<and>* zero (u + int k + 1) \<and>* zero (u + int k + 2)"])
apply (hsteps)
apply (rule_tac p = "st j' \<and>* ps (u - 1) \<and>* ones (u - 1) (u + int k) \<and>*
zero (u + int k + 1) \<and>* zero (u + int k + 2)"
in tm.pre_stren)
apply (hsteps)
my_block
have "(ones (u - 1) (u + int k)) = (ones (u - 1) (u + int k - 1) \<and>* one (u + int k))"
by (smt ones_rev)
my_block_end
apply (unfold this)
apply hsteps
apply (simp add:sep_conj_ac, sep_cancel+)
apply (smt ones.simps sep.mult_assoc sep_conj_commuteI)
apply (simp add:sep_conj_ac)+
apply (sep_cancel+)
apply (smt ones.simps sep.mult_left_commute sep_conj_commuteI this)
by hstep
with True show ?thesis
by (simp add:ones_simps, simp only:sep_conj_cond, intro tm.pre_condI, simp)
next
case False
let ?body = "i :[ (if_zero j ; move_left ; write_one ;right_until_zero ; move_left ;
write_zero ; move_right ; move_right ; jmp i) ]: j"
have "\<lbrace>st i \<and>* ps u \<and>* tm (u - 1) x \<and>* one u \<and>* ones (u + 1) (u + int k) \<and>*
zero (u + int k + 1) \<and>* reps (u + int k + 2) v ks \<and>* zero (v + 1) \<and>* zero (v + 2)\<rbrace>
?body
\<lbrace>st j \<and>* ps (v + 2) \<and>* one (u - 1) \<and>* ones u (u - 1 + int k) \<and>*
zero (u + int k) \<and>* reps (1 + (u + int k)) (v - 1) ks \<and>*
zero v \<and>* zero (v + 1) \<and>* zero (v + 2)\<rbrace>"
apply (rule tm.sequencing[where q = "st i \<and>* ps (u + int k + 2) \<and>*
zero (u + int k + 1) \<and>* reps (u + int k + 2) v ks \<and>* zero (v + 1) \<and>*
zero (v + 2) \<and>* one (u - 1) \<and>* ones u (u - 1 + int k) \<and>* zero (u + int k)"])
apply (hsteps)
apply (rule_tac p = "st j' \<and>* ps (u - 1) \<and>*
ones (u - 1) (u + int k) \<and>*
zero (u + int k + 1) \<and>*
reps (u + int k + 2) v ks \<and>* zero (v + 1) \<and>* zero (v + 2)
" in tm.pre_stren)
apply hsteps
my_block
have "(ones (u - 1) (u + int k)) =
(ones (u - 1) (u + int k - 1) \<and>* one (u + int k))"
by (smt ones_rev)
my_block_end
apply (unfold this)
apply (hsteps)
apply (sep_cancel+)
apply (smt ones.simps sep.mult_assoc sep_conj_commuteI)
apply (sep_cancel+)
apply (smt ones.simps this)
my_block
have eq_u: "1 + (u + int k) = u + int k + 1" by simp
from Cons.hyps[OF `ks \<noteq> []`, of i "u + int k + 2" Bk v, folded zero_def]
have "\<lbrace>st i \<and>* ps (u + int k + 2) \<and>* zero (u + int k + 1) \<and>*
reps (u + int k + 2) v ks \<and>* zero (v + 1) \<and>* zero (v + 2)\<rbrace>
?body
\<lbrace>st j \<and>* ps (v + 2) \<and>* reps (1 + (u + int k)) (v - 1) ks \<and>*
zero v \<and>* zero (v + 1) \<and>* zero (v + 2)\<rbrace>"
by (simp add:eq_u)
my_block_end my_note hh[step] = this
by hsteps
thus ?thesis
by (unfold reps_simp3[OF False], auto simp:sep_conj_ac ones_simps)
qed
qed auto
qed
lemma hoare_shift_left_cons_gen[step]:
assumes h: "ks \<noteq> []"
"v = u - 1" "w = u" "y = x + 1" "z = x + 2"
shows "\<lbrace>st i \<and>* ps u \<and>* tm v vv \<and>* reps w x ks \<and>* tm y Bk \<and>* tm z Bk\<rbrace>
i:[shift_left]:j
\<lbrace>st j \<and>* ps z \<and>* reps v (x - 1) ks \<and>* zero x \<and>* zero y \<and>* zero z \<rbrace>"
by (unfold assms, fold zero_def, rule hoare_shift_left_cons[OF `ks \<noteq> []`])
definition "bone c1 c2 = (TL exit l_one.
if_one l_one;
(c1;
jmp exit);
TLabel l_one;
c2;
TLabel exit
)"
lemma hoare_bone_1_out:
assumes h:
"\<And> i j . \<lbrace>st i \<and>* ps u \<and>* zero u \<and>* p \<rbrace>
i:[c1]:j
\<lbrace>st e \<and>* q \<rbrace>
"
shows "\<lbrace>st i \<and>* ps u \<and>* zero u \<and>* p \<rbrace>
i:[(bone c1 c2)]:j
\<lbrace>st e \<and>* q \<rbrace>
"
apply (unfold bone_def, intro t_hoare_local)
apply hsteps
apply (subst tassemble_to.simps(2), intro tm.code_exI, rule tm.code_extension)
apply (subst tassemble_to.simps(2), intro tm.code_exI, rule tm.code_extension)
by (rule h)
lemma hoare_bone_1:
assumes h:
"\<And> i j . \<lbrace>st i \<and>* ps u \<and>* zero u \<and>* p \<rbrace>
i:[c1]:j
\<lbrace>st j \<and>* ps v \<and>* tm v x \<and>* q \<rbrace>
"
shows "\<lbrace>st i \<and>* ps u \<and>* zero u \<and>* p \<rbrace>
i:[(bone c1 c2)]:j
\<lbrace>st j \<and>* ps v \<and>* tm v x \<and>* q \<rbrace>
"
proof -
note h[step]
show ?thesis
apply (unfold bone_def, intro t_hoare_local)
apply (rule t_hoare_label_last, auto)
apply hsteps
apply (subst tassemble_to.simps(2), intro tm.code_exI, rule tm.code_extension)
by hsteps
qed
lemma hoare_bone_2:
assumes h:
"\<And> i j . \<lbrace>st i \<and>* ps u \<and>* one u \<and>* p \<rbrace>
i:[c2]:j
\<lbrace>st j \<and>* q \<rbrace>
"
shows "\<lbrace>st i \<and>* ps u \<and>* one u \<and>* p \<rbrace>
i:[(bone c1 c2)]:j
\<lbrace>st j \<and>* q \<rbrace>
"
apply (unfold bone_def, intro t_hoare_local)
apply (rule_tac q = "st la \<and>* ps u \<and>* one u \<and>* p" in tm.sequencing)
apply hsteps
apply (subst tassemble_to.simps(2), intro tm.code_exI, intro tm.code_extension1)
apply (subst tassemble_to.simps(2), intro tm.code_exI, intro tm.code_extension1)
apply (subst tassemble_to.simps(2), intro tm.code_exI)
apply (subst tassemble_to.simps(4), intro tm.code_condI, simp)
apply (subst tassemble_to.simps(2), intro tm.code_exI)
apply (subst tassemble_to.simps(4), simp add:sep_conj_cond, rule tm.code_condI, simp)
by (rule h)
lemma hoare_bone_2_out:
assumes h:
"\<And> i j . \<lbrace>st i \<and>* ps u \<and>* one u \<and>* p \<rbrace>
i:[c2]:j
\<lbrace>st e \<and>* q \<rbrace>
"
shows "\<lbrace>st i \<and>* ps u \<and>* one u \<and>* p \<rbrace>
i:[(bone c1 c2)]:j
\<lbrace>st e \<and>* q \<rbrace>
"
apply (unfold bone_def, intro t_hoare_local)
apply (rule_tac q = "st la \<and>* ps u \<and>* one u \<and>* p" in tm.sequencing)
apply hsteps
apply (subst tassemble_to.simps(2), intro tm.code_exI, rule tm.code_extension1)
apply (subst tassemble_to.simps(2), intro tm.code_exI, rule tm.code_extension1)
apply (subst tassemble_to.simps(2), intro tm.code_exI)
apply (subst tassemble_to.simps(4), rule tm.code_condI, simp)
apply (subst tassemble_to.simps(2), intro tm.code_exI, rule tm.code_extension)
by (rule h)
definition "bzero c1 c2 = (TL exit l_zero.
if_zero l_zero;
(c1;
jmp exit);
TLabel l_zero;
c2;
TLabel exit
)"
lemma hoare_bzero_1:
assumes h[step]:
"\<And> i j . \<lbrace>st i \<and>* ps u \<and>* one u \<and>* p \<rbrace>
i:[c1]:j
\<lbrace>st j \<and>* ps v \<and>* tm v x \<and>* q \<rbrace>
"
shows "\<lbrace>st i \<and>* ps u \<and>* one u \<and>* p \<rbrace>
i:[(bzero c1 c2)]:j
\<lbrace>st j \<and>* ps v \<and>* tm v x \<and>* q \<rbrace>
"
apply (unfold bzero_def, intro t_hoare_local)
apply hsteps
apply (rule_tac c = " ((c1 ; jmp l) ; TLabel la ; c2 ; TLabel l)" in t_hoare_label_last, auto)
apply (subst tassemble_to.simps(2), intro tm.code_exI, intro tm.code_extension)
by hsteps
lemma hoare_bzero_1_out:
assumes h[step]:
"\<And> i j . \<lbrace>st i \<and>* ps u \<and>* one u \<and>* p \<rbrace>
i:[c1]:j
\<lbrace>st e \<and>* q \<rbrace>
"
shows "\<lbrace>st i \<and>* ps u \<and>* one u \<and>* p \<rbrace>
i:[(bzero c1 c2)]:j
\<lbrace>st e \<and>* q \<rbrace>
"
apply (unfold bzero_def, intro t_hoare_local)
apply hsteps
apply (subst tassemble_to.simps(2), intro tm.code_exI, rule tm.code_extension)
apply (subst tassemble_to.simps(2), intro tm.code_exI, rule tm.code_extension)
by (rule h)
lemma hoare_bzero_2:
assumes h:
"\<And> i j. \<lbrace>st i \<and>* ps u \<and>* zero u \<and>* p \<rbrace>
i:[c2]:j
\<lbrace>st j \<and>* q \<rbrace>
"
shows "\<lbrace>st i \<and>* ps u \<and>* zero u \<and>* p \<rbrace>
i:[(bzero c1 c2)]:j
\<lbrace>st j \<and>* q \<rbrace>
"
apply (unfold bzero_def, intro t_hoare_local)
apply (rule_tac q = "st la \<and>* ps u \<and>* zero u \<and>* p" in tm.sequencing)
apply hsteps
apply (subst tassemble_to.simps(2), intro tm.code_exI, intro tm.code_extension1)
apply (subst tassemble_to.simps(2), intro tm.code_exI, intro tm.code_extension1)
apply (subst tassemble_to.simps(2), intro tm.code_exI)
apply (subst tassemble_to.simps(4))
apply (rule tm.code_condI, simp)
apply (subst tassemble_to.simps(2))
apply (rule tm.code_exI)
apply (subst tassemble_to.simps(4), simp add:sep_conj_cond)
apply (rule tm.code_condI, simp)
by (rule h)
lemma hoare_bzero_2_out:
assumes h:
"\<And> i j . \<lbrace>st i \<and>* ps u \<and>* zero u \<and>* p \<rbrace>
i:[c2]:j
\<lbrace>st e \<and>* q \<rbrace>
"
shows "\<lbrace>st i \<and>* ps u \<and>* zero u \<and>* p\<rbrace>
i:[(bzero c1 c2)]:j
\<lbrace>st e \<and>* q \<rbrace>
"
apply (unfold bzero_def, intro t_hoare_local)
apply (rule_tac q = "st la \<and>* ps u \<and>* zero u \<and>* p" in tm.sequencing)
apply hsteps
apply (subst tassemble_to.simps(2), intro tm.code_exI, rule tm.code_extension1)
apply (subst tassemble_to.simps(2), intro tm.code_exI, rule tm.code_extension1)
apply (subst tassemble_to.simps(2), intro tm.code_exI)
apply (subst tassemble_to.simps(4), rule tm.code_condI, simp)
apply (subst tassemble_to.simps(2), intro tm.code_exI, rule tm.code_extension)
by (rule h)
definition "skip_or_set = bone (write_one; move_right; move_right)
(right_until_zero; move_right)"
lemma reps_len_split:
assumes "xs \<noteq> []" "ys \<noteq> []"
shows "reps_len (xs @ ys) = reps_len xs + reps_len ys + 1"
using assms
proof(induct xs arbitrary:ys)
case (Cons x1 xs1)
show ?case
proof(cases "xs1 = []")
case True
thus ?thesis
by (simp add:reps_len_cons[OF `ys \<noteq> []`] reps_len_sg)
next
case False
hence " xs1 @ ys \<noteq> []" by simp
thus ?thesis
apply (simp add:reps_len_cons[OF `xs1@ys \<noteq> []`] reps_len_cons[OF `xs1 \<noteq> []`])
by (simp add: Cons.hyps[OF `xs1 \<noteq> []` `ys \<noteq> []`])
qed
qed auto
lemma hoare_skip_or_set_set:
"\<lbrace> st i \<and>* ps u \<and>* zero u \<and>* zero (u + 1) \<and>* tm (u + 2) x\<rbrace>
i:[skip_or_set]:j
\<lbrace> st j \<and>* ps (u + 2) \<and>* one u \<and>* zero (u + 1) \<and>* tm (u + 2) x\<rbrace>"
apply(unfold skip_or_set_def)
apply(rule_tac q = "st j \<and>* ps (u + 2) \<and>* tm (u + 2) x \<and>* one u \<and>* zero (u + 1)"
in tm.post_weaken)
apply(rule hoare_bone_1)
apply hsteps
by (auto simp:sep_conj_ac, sep_cancel+, smt)
lemma hoare_skip_or_set_set_gen[step]:
assumes "u = v" "w = v + 1" "x = v + 2"
shows "\<lbrace>st i \<and>* ps u \<and>* zero v \<and>* zero w \<and>* tm x xv\<rbrace>
i:[skip_or_set]:j
\<lbrace>st j \<and>* ps x \<and>* one v \<and>* zero w \<and>* tm x xv\<rbrace>"
by (unfold assms, rule hoare_skip_or_set_set)
lemma hoare_skip_or_set_skip:
"\<lbrace> st i \<and>* ps u \<and>* reps u v [k] \<and>* zero (v + 1)\<rbrace>
i:[skip_or_set]:j
\<lbrace> st j \<and>* ps (v + 2) \<and>* reps u v [k] \<and>* zero (v + 1)\<rbrace>"
proof -
show ?thesis
apply(unfold skip_or_set_def, unfold reps.simps, simp add:sep_conj_cond)
apply(rule tm.pre_condI, simp)
apply(rule_tac p = "st i \<and>* ps u \<and>* one u \<and>* ones (u + 1) (u + int k) \<and>*
zero (u + int k + 1)"
in tm.pre_stren)
apply (rule_tac q = "st j \<and>* ps (u + int k + 2) \<and>*
one u \<and>* ones (u + 1) (u + int k) \<and>* zero (u + int k + 1)
" in tm.post_weaken)
apply (rule hoare_bone_2)
apply (rule_tac p = " st i \<and>* ps u \<and>* ones u (u + int k) \<and>* zero (u + int k + 1)
" in tm.pre_stren)
apply hsteps
apply (simp add:sep_conj_ac, sep_cancel+, auto simp:sep_conj_ac ones_simps)
by (sep_cancel+, smt)
qed
lemma hoare_skip_or_set_skip_gen[step]:
assumes "u = v" "x = w + 1"
shows "\<lbrace> st i \<and>* ps u \<and>* reps v w [k] \<and>* zero x\<rbrace>
i:[skip_or_set]:j
\<lbrace> st j \<and>* ps (w + 2) \<and>* reps v w [k] \<and>* zero x\<rbrace>"
by (unfold assms, rule hoare_skip_or_set_skip)
definition "if_reps_z e = (move_right;
bone (move_left; jmp e) (move_left)
)"
lemma hoare_if_reps_z_true:
assumes h: "k = 0"
shows
"\<lbrace>st i \<and>* ps u \<and>* reps u v [k] \<and>* zero (v + 1)\<rbrace>
i:[if_reps_z e]:j
\<lbrace>st e \<and>* ps u \<and>* reps u v [k] \<and>* zero (v + 1)\<rbrace>"
apply (unfold reps.simps, simp add:sep_conj_cond)
apply (rule tm.pre_condI, simp add:h)
apply (unfold if_reps_z_def)
apply (simp add:ones_simps)
apply (hsteps)
apply (rule_tac p = "st j' \<and>* ps (u + 1) \<and>* zero (u + 1) \<and>* one u" in tm.pre_stren)
apply (rule hoare_bone_1_out)
by (hsteps)
lemma hoare_if_reps_z_true_gen[step]:
assumes "k = 0" "u = v" "x = w + 1"
shows "\<lbrace>st i \<and>* ps u \<and>* reps v w [k] \<and>* zero x\<rbrace>
i:[if_reps_z e]:j
\<lbrace>st e \<and>* ps u \<and>* reps v w [k] \<and>* zero x\<rbrace>"
by (unfold assms, rule hoare_if_reps_z_true, simp)
lemma hoare_if_reps_z_false:
assumes h: "k \<noteq> 0"
shows
"\<lbrace>st i \<and>* ps u \<and>* reps u v [k]\<rbrace>
i:[if_reps_z e]:j
\<lbrace>st j \<and>* ps u \<and>* reps u v [k]\<rbrace>"
proof -
from h obtain k' where "k = Suc k'" by (metis not0_implies_Suc)
show ?thesis
apply (unfold `k = Suc k'`)
apply (simp add:sep_conj_cond, rule tm.pre_condI, simp)
apply (unfold if_reps_z_def)
apply (simp add:ones_simps)
apply hsteps
apply (rule_tac p = "st j' \<and>* ps (u + 1) \<and>* one (u + 1) \<and>* one u \<and>*
ones (2 + u) (u + (1 + int k'))" in tm.pre_stren)
apply (rule_tac hoare_bone_2)
by (hsteps)
qed
lemma hoare_if_reps_z_false_gen[step]:
assumes h: "k \<noteq> 0" "u = v"
shows
"\<lbrace>st i \<and>* ps u \<and>* reps v w [k]\<rbrace>
i:[if_reps_z e]:j
\<lbrace>st j \<and>* ps u \<and>* reps v w [k]\<rbrace>"
by (unfold assms, rule hoare_if_reps_z_false[OF `k \<noteq> 0`])
definition "if_reps_nz e = (move_right;
bzero (move_left; jmp e) (move_left)
)"
lemma EXS_postI:
assumes "\<lbrace>P\<rbrace>
c
\<lbrace>Q x\<rbrace>"
shows "\<lbrace>P\<rbrace>
c
\<lbrace>EXS x. Q x\<rbrace>"
by (metis EXS_intro assms tm.hoare_adjust)
lemma hoare_if_reps_nz_true:
assumes h: "k \<noteq> 0"
shows
"\<lbrace>st i \<and>* ps u \<and>* reps u v [k]\<rbrace>
i:[if_reps_nz e]:j
\<lbrace>st e \<and>* ps u \<and>* reps u v [k]\<rbrace>"
proof -
from h obtain k' where "k = Suc k'" by (metis not0_implies_Suc)
show ?thesis
apply (unfold `k = Suc k'`)
apply (unfold reps.simps, simp add:sep_conj_cond, rule tm.pre_condI, simp)
apply (unfold if_reps_nz_def)
apply (simp add:ones_simps)
apply hsteps
apply (rule_tac p = "st j' \<and>* ps (u + 1) \<and>* one (u + 1) \<and>* one u \<and>*
ones (2 + u) (u + (1 + int k'))" in tm.pre_stren)
apply (rule hoare_bzero_1_out)
by hsteps
qed
lemma hoare_if_reps_nz_true_gen[step]:
assumes h: "k \<noteq> 0" "u = v"
shows
"\<lbrace>st i \<and>* ps u \<and>* reps v w [k]\<rbrace>
i:[if_reps_nz e]:j
\<lbrace>st e \<and>* ps u \<and>* reps v w [k]\<rbrace>"
by (unfold assms, rule hoare_if_reps_nz_true[OF `k\<noteq> 0`])
lemma hoare_if_reps_nz_false:
assumes h: "k = 0"
shows
"\<lbrace>st i \<and>* ps u \<and>* reps u v [k] \<and>* zero (v + 1)\<rbrace>
i:[if_reps_nz e]:j
\<lbrace>st j \<and>* ps u \<and>* reps u v [k] \<and>* zero (v + 1)\<rbrace>"
apply (simp add:h sep_conj_cond)
apply (rule tm.pre_condI, simp)
apply (unfold if_reps_nz_def)
apply (simp add:ones_simps)
apply (hsteps)
apply (rule_tac p = "st j' \<and>* ps (u + 1) \<and>* zero (u + 1) \<and>* one u" in tm.pre_stren)
apply (rule hoare_bzero_2)
by (hsteps)
lemma hoare_if_reps_nz_false_gen[step]:
assumes h: "k = 0" "u = v" "x = w + 1"
shows
"\<lbrace>st i \<and>* ps u \<and>* reps v w [k] \<and>* zero x\<rbrace>
i:[if_reps_nz e]:j
\<lbrace>st j \<and>* ps u \<and>* reps v w [k] \<and>* zero x\<rbrace>"
by (unfold assms, rule hoare_if_reps_nz_false, simp)
definition "skip_or_sets n = tpg_fold (replicate n skip_or_set)"
lemma hoare_skip_or_sets_set:
shows "\<lbrace>st i \<and>* ps u \<and>* zeros u (u + int (reps_len (replicate (Suc n) 0))) \<and>*
tm (u + int (reps_len (replicate (Suc n) 0)) + 1) x\<rbrace>
i:[skip_or_sets (Suc n)]:j
\<lbrace>st j \<and>* ps (u + int (reps_len (replicate (Suc n) 0)) + 1) \<and>*
reps' u (u + int (reps_len (replicate (Suc n) 0))) (replicate (Suc n) 0) \<and>*
tm (u + int (reps_len (replicate (Suc n) 0)) + 1) x \<rbrace>"
proof(induct n arbitrary:i j u x)
case 0
from 0 show ?case
apply (simp add:reps'_def reps_len_def reps_ctnt_len_def reps_sep_len_def reps.simps)
apply (unfold skip_or_sets_def, simp add:tpg_fold_sg)
apply hsteps
by (auto simp:sep_conj_ac, smt cond_true_eq2 ones.simps sep_conj_left_commute)
next
case (Suc n)
{ fix n
have "listsum (replicate n (Suc 0)) = n"
by (induct n, auto)
} note eq_sum = this
have eq_len: "\<And>n. n \<noteq> 0 \<Longrightarrow> reps_len (replicate (Suc n) 0) = reps_len (replicate n 0) + 2"
by (simp add:reps_len_def reps_sep_len_def reps_ctnt_len_def)
have eq_zero: "\<And> u v. (zeros u (u + int (v + 2))) =
(zeros u (u + (int v)) \<and>* zero (u + (int v) + 1) \<and>* zero (u + (int v) + 2))"
by (smt sep.mult_assoc zeros_rev)
hence eq_z:
"zeros u (u + int (reps_len (replicate (Suc (Suc n)) 0))) =
(zeros u (u + int (reps_len (replicate (Suc n) 0))) \<and>*
zero ((u + int (reps_len (replicate (Suc n) 0))) + 1) \<and>*
zero ((u + int (reps_len (replicate (Suc n) 0))) + 2))
" by (simp only:eq_len)
have hh: "\<And>x. (replicate (Suc (Suc n)) x) = (replicate (Suc n) x) @ [x]"
by (metis replicate_Suc replicate_append_same)
have hhh: "replicate (Suc n) skip_or_set \<noteq> []" "[skip_or_set] \<noteq> []" by auto
have eq_code:
"(i :[ skip_or_sets (Suc (Suc n)) ]: j) =
(i :[ (skip_or_sets (Suc n); skip_or_set) ]: j)"
proof(unfold skip_or_sets_def)
show "i :[ tpg_fold (replicate (Suc (Suc n)) skip_or_set) ]: j =
i :[ (tpg_fold (replicate (Suc n) skip_or_set) ; skip_or_set) ]: j"
apply (insert tpg_fold_app[OF hhh, of i j], unfold hh)
by (simp only:tpg_fold_sg)
qed
have "Suc n \<noteq> 0" by simp
show ?case
apply (unfold eq_z eq_code)
apply (hstep Suc(1))
apply (unfold eq_len[OF `Suc n \<noteq> 0`])
apply hstep
apply (auto simp:sep_conj_ac)[1]
apply (sep_cancel+, prune)
apply (fwd abs_ones)
apply ((fwd abs_reps')+, simp add:int_add_ac)
by (metis replicate_append_same)
qed
lemma hoare_skip_or_sets_set_gen[step]:
assumes h: "p2 = p1"
"p3 = p1 + int (reps_len (replicate (Suc n) 0))"
"p4 = p3 + 1"
shows "\<lbrace>st i \<and>* ps p1 \<and>* zeros p2 p3 \<and>* tm p4 x\<rbrace>
i:[skip_or_sets (Suc n)]:j
\<lbrace>st j \<and>* ps p4 \<and>* reps' p2 p3 (replicate (Suc n) 0) \<and>* tm p4 x\<rbrace>"
apply (unfold h)
by (rule hoare_skip_or_sets_set)
declare reps.simps[simp del]
lemma hoare_skip_or_sets_skip:
assumes h: "n < length ks"
shows "\<lbrace>st i \<and>* ps u \<and>* reps' u v (take n ks) \<and>* reps' (v + 1) w [ks!n] \<rbrace>
i:[skip_or_sets (Suc n)]:j
\<lbrace>st j \<and>* ps (w+1) \<and>* reps' u v (take n ks) \<and>* reps' (v + 1) w [ks!n]\<rbrace>"
using h
proof(induct n arbitrary: i j u v w ks)
case 0
show ?case
apply (subst (1 5) reps'_def, simp add:sep_conj_cond, intro tm.pre_condI, simp)
apply (unfold skip_or_sets_def, simp add:tpg_fold_sg)
apply (unfold reps'_def, simp del:reps.simps)
apply hsteps
by (sep_cancel+, smt+)
next
case (Suc n)
from `Suc n < length ks` have "n < length ks" by auto
note h = Suc(1) [OF this]
show ?case
my_block
from `Suc n < length ks`
have eq_take: "take (Suc n) ks = take n ks @ [ks!n]"
by (metis not_less_eq not_less_iff_gr_or_eq take_Suc_conv_app_nth)
my_block_end
apply (unfold this)
apply (subst reps'_append, simp add:sep_conj_exists, rule tm.precond_exI)
my_block
have "(i :[ skip_or_sets (Suc (Suc n)) ]: j) =
(i :[ (skip_or_sets (Suc n); skip_or_set )]: j)"
proof -
have eq_rep:
"(replicate (Suc (Suc n)) skip_or_set) = ((replicate (Suc n) skip_or_set) @ [skip_or_set])"
by (metis replicate_Suc replicate_append_same)
have "replicate (Suc n) skip_or_set \<noteq> []" "[skip_or_set] \<noteq> []" by auto
from tpg_fold_app[OF this]
show ?thesis
by (unfold skip_or_sets_def eq_rep, simp del:replicate.simps add:tpg_fold_sg)
qed
my_block_end
apply (unfold this)
my_block
fix i j m
have "\<lbrace>st i \<and>* ps u \<and>* (reps' u (m - 1) (take n ks) \<and>* reps' m v [ks ! n])\<rbrace>
i :[ (skip_or_sets (Suc n)) ]: j
\<lbrace>st j \<and>* ps (v + 1) \<and>* (reps' u (m - 1) (take n ks) \<and>* reps' m v [ks ! n])\<rbrace>"
apply (rule h[THEN tm.hoare_adjust])
by (sep_cancel+, auto)
my_block_end my_note h_c1 = this
my_block
fix j' j m
have "\<lbrace>st j' \<and>* ps (v + 1) \<and>* reps' (v + 1) w [ks ! Suc n]\<rbrace>
j' :[ skip_or_set ]: j
\<lbrace>st j \<and>* ps (w + 1) \<and>* reps' (v + 1) w [ks ! Suc n]\<rbrace>"
apply (unfold reps'_def, simp)
apply (rule hoare_skip_or_set_skip[THEN tm.hoare_adjust])
by (sep_cancel+, smt)+
my_block_end
apply (hstep h_c1 this)+
by ((fwd abs_reps'), simp, sep_cancel+)
qed
lemma hoare_skip_or_sets_skip_gen[step]:
assumes h: "n < length ks" "u = v" "x = w + 1"
shows "\<lbrace>st i \<and>* ps u \<and>* reps' v w (take n ks) \<and>* reps' x y [ks!n] \<rbrace>
i:[skip_or_sets (Suc n)]:j
\<lbrace>st j \<and>* ps (y+1) \<and>* reps' v w (take n ks) \<and>* reps' x y [ks!n]\<rbrace>"
by (unfold assms, rule hoare_skip_or_sets_skip[OF `n < length ks`])
lemma fam_conj_interv_simp:
"(fam_conj {(ia::int)<..} p) = ((p (ia + 1)) \<and>* fam_conj {ia + 1 <..} p)"
by (smt Collect_cong fam_conj_insert_simp greaterThan_def
greaterThan_eq_iff greaterThan_iff insertI1
insert_compr lessThan_iff mem_Collect_eq)
lemma zeros_fam_conj:
assumes "u \<le> v"
shows "(zeros u v \<and>* fam_conj {v<..} zero) = fam_conj {u - 1<..} zero"
proof -
have "{u - 1<..v} ## {v <..}" by (auto simp:set_ins_def)
from fam_conj_disj_simp[OF this, symmetric]
have "(fam_conj {u - 1<..v} zero \<and>* fam_conj {v<..} zero) = fam_conj ({u - 1<..v} + {v<..}) zero" .
moreover
from `u \<le> v` have eq_set: "{u - 1 <..} = {u - 1 <..v} + {v <..}" by (auto simp:set_ins_def)
moreover have "fam_conj {u - 1<..v} zero = zeros u v"
proof -
have "({u - 1<..v}) = ({u .. v})" by auto
moreover {
fix u v
assume "u \<le> (v::int)"
hence "fam_conj {u .. v} zero = zeros u v"
proof(induct rule:ones_induct)
case (Base i j)
thus ?case by auto
next
case (Step i j)
thus ?case
proof(cases "i = j")
case True
show ?thesis
by (unfold True, simp add:fam_conj_simps)
next
case False
with `i \<le> j` have hh: "i + 1 \<le> j" by auto
hence eq_set: "{i..j} = (insert i {i + 1 .. j})"
by (smt simp_from_to)
have "i \<notin> {i + 1 .. j}" by simp
from fam_conj_insert_simp[OF this, folded eq_set]
have "fam_conj {i..j} zero = (zero i \<and>* fam_conj {i + 1..j} zero)" .
with Step(2)[OF hh] Step
show ?thesis by simp
qed
qed
}
moreover note this[OF `u \<le> v`]
ultimately show ?thesis by simp
qed
ultimately show ?thesis by smt
qed
declare replicate.simps [simp del]
lemma hoare_skip_or_sets_comb:
assumes "length ks \<le> n"
shows "\<lbrace>st i \<and>* ps u \<and>* reps u v ks \<and>* fam_conj {v<..} zero\<rbrace>
i:[skip_or_sets (Suc n)]:j
\<lbrace>st j \<and>* ps ((v + int (reps_len (list_ext n ks)) - int (reps_len ks))+ 2) \<and>*
reps' u (v + int (reps_len (list_ext n ks)) - int (reps_len ks) + 1) (list_ext n ks) \<and>*
fam_conj {(v + int (reps_len (list_ext n ks)) - int (reps_len ks) + 1)<..} zero \<rbrace>"
proof(cases "ks = []")
case True
show ?thesis
apply (subst True, simp only:reps.simps sep_conj_cond)
apply (rule tm.pre_condI, simp)
apply (rule_tac p = "st i \<and>* ps (v + 1) \<and>*
zeros (v + 1) (v + 1 + int (reps_len (replicate (Suc n) 0))) \<and>*
tm (v + 2 + int (reps_len (replicate (Suc n) 0))) Bk \<and>*
fam_conj {(v + 2 + int (reps_len (replicate (Suc n) 0)))<..} zero
" in tm.pre_stren)
apply hsteps
apply (auto simp:sep_conj_ac)[1]
apply (auto simp:sep_conj_ac)[2]
my_block
from True have "(list_ext n ks) = (replicate (Suc n) 0)"
by (metis append_Nil diff_zero list.size(3) list_ext_def)
my_block_end my_note le_red = this
my_block
from True have "(reps_len ks) = 0"
by (metis reps_len_nil)
my_block_end
apply (unfold this le_red, simp)
my_block
have "v + 2 + int (reps_len (replicate (Suc n) 0)) =
v + int (reps_len (replicate (Suc n) 0)) + 2" by smt
my_block_end my_note eq_len = this
apply (unfold this)
apply (sep_cancel+)
apply (fold zero_def)
apply (subst fam_conj_interv_simp, simp)
apply (simp only:int_add_ac)
apply (simp only:sep_conj_ac, sep_cancel+)
my_block
have "v + 1 \<le> (2 + (v + int (reps_len (replicate (Suc n) 0))))" by simp
from zeros_fam_conj[OF this]
have "(fam_conj {v<..} zero) = (zeros (v + 1) (2 + (v + int (reps_len (replicate (Suc n) 0)))) \<and>*
fam_conj {2 + (v + int (reps_len (replicate (Suc n) 0)))<..} zero)"
by simp
my_block_end
apply (subst (asm) this, simp only:int_add_ac, sep_cancel+)
by (smt cond_true_eq2 sep.mult_assoc sep.mult_commute
sep.mult_left_commute sep_conj_assoc sep_conj_commute
sep_conj_left_commute zeros.simps zeros_rev)
next
case False
show ?thesis
my_block
have "(i:[skip_or_sets (Suc n)]:j) =
(i:[(skip_or_sets (length ks); skip_or_sets (Suc n - length ks))]:j)"
apply (unfold skip_or_sets_def)
my_block
have "(replicate (Suc n) skip_or_set) =
(replicate (length ks) skip_or_set @ (replicate (Suc n - length ks) skip_or_set))"
by (smt assms replicate_add)
my_block_end
apply (unfold this, rule tpg_fold_app, simp add:False)
by (insert `length ks \<le> n`, simp)
my_block_end
apply (unfold this)
my_block
from False have "length ks = (Suc (length ks - 1))" by simp
my_block_end
apply (subst (1) this)
my_block
from False
have "(reps u v ks \<and>* fam_conj {v<..} zero) =
(reps' u (v + 1) ks \<and>* fam_conj {v+1<..} zero)"
apply (unfold reps'_def, simp)
by (subst fam_conj_interv_simp, simp add:sep_conj_ac)
my_block_end
apply (unfold this)
my_block
fix i j
have "\<lbrace>st i \<and>* ps u \<and>* reps' u (v + 1) ks \<rbrace>
i :[ skip_or_sets (Suc (length ks - 1))]: j
\<lbrace>st j \<and>* ps (v + 2) \<and>* reps' u (v + 1) ks \<rbrace>"
my_block
have "ks = take (length ks - 1) ks @ [ks!(length ks - 1)]"
by (smt False drop_0 drop_eq_Nil id_take_nth_drop)
my_block_end my_note eq_ks = this
apply (subst (1) this)
apply (unfold reps'_append, simp add:sep_conj_exists, rule tm.precond_exI)
my_block
from False have "(length ks - Suc 0) < length ks"
by (smt `length ks = Suc (length ks - 1)`)
my_block_end
apply hsteps
apply (subst eq_ks, unfold reps'_append, simp only:sep_conj_exists)
by (rule_tac x = m in EXS_intro, simp add:sep_conj_ac, sep_cancel+, smt)
my_block_end
apply (hstep this)
my_block
fix u n
have "(fam_conj {u <..} zero) =
(zeros (u + 1) (u + int n + 1) \<and>* tm (u + int n + 2) Bk \<and>* fam_conj {(u + int n + 2)<..} zero)"
my_block
have "u + 1 \<le> (u + int n + 2)" by auto
from zeros_fam_conj[OF this, symmetric]
have "fam_conj {u<..} zero = (zeros (u + 1) (u + int n + 2) \<and>* fam_conj {u + int n + 2<..} zero)"
by simp
my_block_end
apply (subst this)
my_block
have "(zeros (u + 1) (u + int n + 2)) =
((zeros (u + 1) (u + int n + 1) \<and>* tm (u + int n + 2) Bk))"
by (smt zero_def zeros_rev)
my_block_end
by (unfold this, auto simp:sep_conj_ac)
my_block_end
apply (subst (1) this[of _ "(reps_len (replicate (Suc (n - length ks)) 0))"])
my_block
from `length ks \<le> n`
have "Suc n - length ks = Suc (n - length ks)" by auto
my_block_end my_note eq_suc = this
apply (subst this)
apply hsteps
apply (simp add: sep_conj_ac this, sep_cancel+)
apply (fwd abs_reps')+
my_block
have "(int (reps_len (replicate (Suc (n - length ks)) 0))) =
(int (reps_len (list_ext n ks)) - int (reps_len ks) - 1)"
apply (unfold list_ext_def eq_suc)
my_block
have "replicate (Suc (n - length ks)) 0 \<noteq> []" by simp
my_block_end
by (unfold reps_len_split[OF False this], simp)
my_block_end
apply (unfold this)
my_block
from `length ks \<le> n`
have "(ks @ replicate (Suc (n - length ks)) 0) = (list_ext n ks)"
by (unfold list_ext_def, simp)
my_block_end
apply (unfold this, simp)
apply (subst fam_conj_interv_simp, unfold zero_def, simp, simp add:int_add_ac sep_conj_ac)
by (sep_cancel+, smt)
qed
lemma hoare_skip_or_sets_comb_gen:
assumes "length ks \<le> n" "u = v" "w = x"
shows "\<lbrace>st i \<and>* ps u \<and>* reps v w ks \<and>* fam_conj {x<..} zero\<rbrace>
i:[skip_or_sets (Suc n)]:j
\<lbrace>st j \<and>* ps ((x + int (reps_len (list_ext n ks)) - int (reps_len ks))+ 2) \<and>*
reps' u (x + int (reps_len (list_ext n ks)) - int (reps_len ks) + 1) (list_ext n ks) \<and>*
fam_conj {(x + int (reps_len (list_ext n ks)) - int (reps_len ks) + 1)<..} zero \<rbrace>"
by (unfold assms, rule hoare_skip_or_sets_comb[OF `length ks \<le> n`])
definition "locate n = (skip_or_sets (Suc n);
move_left;
move_left;
left_until_zero;
move_right
)"
lemma list_ext_tail_expand:
assumes h: "length ks \<le> a"
shows "list_ext a ks = take a (list_ext a ks) @ [(list_ext a ks)!a]"
proof -
let ?l = "list_ext a ks"
from h have eq_len: "length ?l = Suc a"
by (smt list_ext_len_eq)
hence "?l \<noteq> []" by auto
hence "?l = take (length ?l - 1) ?l @ [?l!(length ?l - 1)]"
by (metis `length (list_ext a ks) = Suc a` diff_Suc_1 le_refl
lessI take_Suc_conv_app_nth take_all)
from this[unfolded eq_len]
show ?thesis by simp
qed
lemma reps'_nn_expand:
assumes "xs \<noteq> []"
shows "(reps' u v xs) = (reps u (v - 1) xs \<and>* zero v)"
by (metis assms reps'_def)
lemma sep_conj_st1: "(p \<and>* st t \<and>* q) = (st t \<and>* p \<and>* q)"
by (simp only:sep_conj_ac)
lemma sep_conj_st2: "(p \<and>* st t) = (st t \<and>* p)"
by (simp only:sep_conj_ac)
lemma sep_conj_st3: "((st t \<and>* p) \<and>* r) = (st t \<and>* p \<and>* r)"
by (simp only:sep_conj_ac)
lemma sep_conj_st4: "(EXS x. (st t \<and>* r x)) = ((st t) \<and>* (EXS x. r x))"
apply (unfold pred_ex_def, default+)
apply (safe)
apply (sep_cancel, auto)
by (auto elim!: sep_conjE intro!:sep_conjI)
lemmas sep_conj_st = sep_conj_st1 sep_conj_st2 sep_conj_st3 sep_conj_st4
lemma sep_conj_cond3 : "(<cond1> \<and>* <cond2>) = <(cond1 \<and> cond2)>"
by (smt cond_eqI cond_true_eq sep_conj_commute sep_conj_empty)
lemma sep_conj_cond4 : "(<cond1> \<and>* <cond2> \<and>* r) = (<(cond1 \<and> cond2)> \<and>* r)"
by (metis Hoare_gen.sep_conj_cond3 Hoare_tm.sep_conj_cond3)
lemmas sep_conj_cond = sep_conj_cond3 sep_conj_cond4 sep_conj_cond
lemma hoare_left_until_zero_reps:
"\<lbrace>st i ** ps v ** zero u ** reps (u + 1) v [k]\<rbrace>
i:[left_until_zero]:j
\<lbrace>st j ** ps u ** zero u ** reps (u + 1) v [k]\<rbrace>"
apply (unfold reps.simps, simp only:sep_conj_cond)
apply (rule tm.pre_condI, simp)
by hstep
lemma hoare_left_until_zero_reps_gen[step]:
assumes "u = x" "w = v + 1"
shows "\<lbrace>st i ** ps u ** zero v ** reps w x [k]\<rbrace>
i:[left_until_zero]:j
\<lbrace>st j ** ps v ** zero v ** reps w x [k]\<rbrace>"
by (unfold assms, rule hoare_left_until_zero_reps)
lemma reps_lenE:
assumes "reps u v ks s"
shows "( <(v = u + int (reps_len ks) - 1)> \<and>* reps u v ks ) s"
proof(rule condI)
from reps_len_correct[OF assms] show "v = u + int (reps_len ks) - 1" .
next
from assms show "reps u v ks s" .
qed
lemma condI1:
assumes "p s" "b"
shows "(<b> \<and>* p) s"
proof(rule condI[OF assms(2)])
from assms(1) show "p s" .
qed
lemma hoare_locate_set:
assumes "length ks \<le> n"
shows "\<lbrace>st i \<and>* zero (u - 1) \<and>* ps u \<and>* reps u v ks \<and>* fam_conj {v<..} zero\<rbrace>
i:[locate n]:j
\<lbrace>st j \<and>* zero (u - 1) \<and>*
(EXS m w. ps m \<and>* reps' u (m - 1) (take n (list_ext n ks)) \<and>*
reps m w [(list_ext n ks)!n] \<and>* fam_conj {w<..} zero)\<rbrace>"
proof(cases "take n (list_ext n ks) = []")
case False
show ?thesis
apply (unfold locate_def)
apply (hstep hoare_skip_or_sets_comb_gen)
apply (subst (3) list_ext_tail_expand[OF `length ks \<le> n`])
apply (subst (1) reps'_append, simp add:sep_conj_exists)
apply (rule tm.precond_exI)
apply (subst (1) reps'_nn_expand[OF False])
apply (rule_tac p = "st j' \<and>* <(m = u + int (reps_len (take n (list_ext n ks))) + 1)> \<and>*
ps (v + int (reps_len (list_ext n ks)) - int (reps_len ks) + 2) \<and>*
((reps u (m - 1 - 1) (take n (list_ext n ks)) \<and>* zero (m - 1)) \<and>*
reps' m (v + int (reps_len (list_ext n ks)) - int (reps_len ks) + 1)
[list_ext n ks ! n]) \<and>*
fam_conj
{v + int (reps_len (list_ext n ks)) - int (reps_len ks) + 1<..}
zero \<and>*
zero (u - 1)"
in tm.pre_stren)
my_block
have "[list_ext n ks ! n] \<noteq> []" by simp
from reps'_nn_expand[OF this]
have "(reps' m (v + int (reps_len (list_ext n ks)) - int (reps_len ks) + 1) [list_ext n ks ! n]) =
(reps m (v + (int (reps_len (list_ext n ks)) - int (reps_len ks))) [list_ext n ks ! n] \<and>*
zero (v + int (reps_len (list_ext n ks)) - int (reps_len ks) + 1))"
by simp
my_block_end
apply (subst this)
my_block
have "(fam_conj {v + int (reps_len (list_ext n ks)) - int (reps_len ks) + 1<..} zero) =
(zero (v + int (reps_len (list_ext n ks)) - int (reps_len ks) + 2) \<and>*
fam_conj {v + int (reps_len (list_ext n ks)) - int (reps_len ks) + 2<..} zero)"
by (subst fam_conj_interv_simp, smt)
my_block_end
apply (unfold this)
apply (simp only:sep_conj_st)
apply hsteps
apply (auto simp:sep_conj_ac)[1]
apply (sep_cancel+)
apply (rule_tac x = m in EXS_intro)
apply (rule_tac x = "m + int (list_ext n ks ! n)" in EXS_intro)
apply (simp add:sep_conj_ac del:ones_simps, sep_cancel+)
apply (subst (asm) sep_conj_cond)+
apply (erule_tac condE, clarsimp, simp add:sep_conj_ac int_add_ac)
apply (fwd abs_reps')
apply (fwd abs_reps')
apply (simp add:sep_conj_ac int_add_ac)
apply (sep_cancel+)
apply (subst (asm) reps'_def, subst fam_conj_interv_simp, subst fam_conj_interv_simp,
simp add:sep_conj_ac int_add_ac)
my_block
fix s
assume h: "(reps (1 + (u + int (reps_len (take n (list_ext n ks)))))
(v + (- int (reps_len ks) + int (reps_len (list_ext n ks)))) [list_ext n ks ! n]) s"
(is "?P s")
from reps_len_correct[OF this] list_ext_tail_expand[OF `length ks \<le> n`]
have hh: "v + (- int (reps_len ks) +
int (reps_len (take n (list_ext n ks) @ [list_ext n ks ! n]))) =
1 + (u + int (reps_len (take n (list_ext n ks)))) +
int (reps_len [list_ext n ks ! n]) - 1"
by metis
have "[list_ext n ks ! n] \<noteq> []" by simp
from hh[unfolded reps_len_split[OF False this]]
have "v = u + (int (reps_len ks)) - 1"
by simp
from condI1[where p = ?P, OF h this]
have "(<(v = u + int (reps_len ks) - 1)> \<and>*
reps (1 + (u + int (reps_len (take n (list_ext n ks)))))
(v + (- int (reps_len ks) + int (reps_len (list_ext n ks)))) [list_ext n ks ! n]) s" .
my_block_end
apply (fwd this, (subst (asm) sep_conj_cond)+, erule condE, simp add:sep_conj_ac int_add_ac
reps_len_sg)
apply (fwd reps_lenE, (subst (asm) sep_conj_cond)+, erule condE, simp add:sep_conj_ac int_add_ac
reps_len_sg)
by (fwd reps_lenE, (subst (asm) sep_conj_cond)+, erule condE, simp add:sep_conj_ac)
next
case True
show ?thesis
apply (unfold locate_def)
apply (hstep hoare_skip_or_sets_comb)
apply (subst (3) list_ext_tail_expand[OF `length ks \<le> n`])
apply (subst (1) reps'_append, simp add:sep_conj_exists)
apply (rule tm.precond_exI)
my_block
from True `length ks \<le> n`
have "ks = []" "n = 0"
apply (metis le0 le_antisym length_0_conv less_nat_zero_code list_ext_len take_eq_Nil)
by (smt True length_take list.size(3) list_ext_len)
my_block_end
apply (unfold True this)
apply (simp add:reps'_def list_ext_def reps.simps reps_len_def reps_sep_len_def
reps_ctnt_len_def
del:ones_simps)
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, simp del:ones_simps)
apply (subst fam_conj_interv_simp, simp add:sep_conj_st del:ones_simps)
apply (hsteps)
apply (auto simp:sep_conj_ac)[1]
apply (sep_cancel+)
apply (rule_tac x = "(v + int (listsum (replicate (Suc 0) (Suc 0))))" in EXS_intro)+
apply (simp only:sep_conj_ac, sep_cancel+)
apply (auto)
apply (subst fam_conj_interv_simp)
apply (subst fam_conj_interv_simp)
by smt
qed
lemma hoare_locate_set_gen[step]:
assumes "length ks \<le> n"
"u = v - 1" "v = w" "x = y"
shows "\<lbrace>st i \<and>* zero u \<and>* ps v \<and>* reps w x ks \<and>* fam_conj {y<..} zero\<rbrace>
i:[locate n]:j
\<lbrace>st j \<and>* zero u \<and>*
(EXS m w. ps m \<and>* reps' v (m - 1) (take n (list_ext n ks)) \<and>*
reps m w [(list_ext n ks)!n] \<and>* fam_conj {w<..} zero)\<rbrace>"
by (unfold assms, rule hoare_locate_set[OF `length ks \<le> n`])
lemma hoare_locate_skip:
assumes h: "n < length ks"
shows
"\<lbrace>st i \<and>* ps u \<and>* zero (u - 1) \<and>* reps' u (v - 1) (take n ks) \<and>* reps' v w [ks!n] \<and>* tm (w + 1) x\<rbrace>
i:[locate n]:j
\<lbrace>st j \<and>* ps v \<and>* zero (u - 1) \<and>* reps' u (v - 1) (take n ks) \<and>* reps' v w [ks!n] \<and>* tm (w + 1) x\<rbrace>"
proof -
show ?thesis
apply (unfold locate_def)
apply hsteps
apply (subst (2 4) reps'_def, simp add:reps.simps sep_conj_cond del:ones_simps)
apply (intro tm.pre_condI, simp del:ones_simps)
apply hsteps
apply (case_tac "(take n ks) = []", simp add:reps'_def sep_conj_cond del:ones_simps)
apply (rule tm.pre_condI, simp del:ones_simps)
apply hsteps
apply (simp del:ones_simps add:reps'_def)
by hsteps
qed
lemma hoare_locate_skip_gen[step]:
assumes "n < length ks"
"v = u - 1" "w = u" "x = y - 1" "z' = z + 1"
shows
"\<lbrace>st i \<and>* ps u \<and>* tm v Bk \<and>* reps' w x (take n ks) \<and>* reps' y z [ks!n] \<and>* tm z' vx\<rbrace>
i:[locate n]:j
\<lbrace>st j \<and>* ps y \<and>* tm v Bk \<and>* reps' w x (take n ks) \<and>* reps' y z [ks!n] \<and>* tm z' vx\<rbrace>"
by (unfold assms, fold zero_def, rule hoare_locate_skip[OF `n < length ks`])
definition "Inc a = locate a;
right_until_zero;
move_right;
shift_right;
move_left;
left_until_double_zero;
write_one;
left_until_double_zero;
move_right;
move_right
"
lemma ones_int_expand: "(ones m (m + int k)) = (one m \<and>* ones (m + 1) (m + int k))"
by (simp add:ones_simps)
lemma reps_splitedI:
assumes h1: "(reps u v ks1 \<and>* zero (v + 1) \<and>* reps (v + 2) w ks2) s"
and h2: "ks1 \<noteq> []"
and h3: "ks2 \<noteq> []"
shows "(reps u w (ks1 @ ks2)) s"
proof -
from h2 h3
have "splited (ks1 @ ks2) ks1 ks2" by (auto simp:splited_def)
from h1 obtain s1 where
"(reps u v ks1) s1" by (auto elim:sep_conjE)
from h1 obtain s2 where
"(reps (v + 2) w ks2) s2" by (auto elim:sep_conjE)
from reps_len_correct[OF `(reps u v ks1) s1`]
have eq_v: "v = u + int (reps_len ks1) - 1" .
from reps_len_correct[OF `(reps (v + 2) w ks2) s2`]
have eq_w: "w = v + 2 + int (reps_len ks2) - 1" .
from h1
have "(reps u (u + int (reps_len ks1) - 1) ks1 \<and>*
zero (u + int (reps_len ks1)) \<and>* reps (u + int (reps_len ks1) + 1) w ks2) s"
apply (unfold eq_v eq_w[unfolded eq_v])
by (sep_cancel+, smt)
thus ?thesis
by(unfold reps_splited[OF `splited (ks1 @ ks2) ks1 ks2`], simp)
qed
lemma reps_sucI:
assumes h: "(reps u v (xs@[x]) \<and>* one (1 + v)) s"
shows "(reps u (1 + v) (xs@[Suc x])) s"
proof(cases "xs = []")
case True
from h obtain s' where "(reps u v (xs@[x])) s'" by (auto elim:sep_conjE)
from reps_len_correct[OF this] have " v = u + int (reps_len (xs @ [x])) - 1" .
with True have eq_v: "v = u + int x" by (simp add:reps_len_sg)
have eq_one1: "(one (1 + (u + int x)) \<and>* ones (u + 1) (u + int x)) = ones (u + 1) (1 + (u + int x))"
by (smt ones_rev sep.mult_commute)
from h show ?thesis
apply (unfold True, simp add:eq_v reps.simps sep_conj_cond sep_conj_ac ones_rev)
by (sep_cancel+, simp add: eq_one1, smt)
next
case False
from h obtain s1 s2 where hh: "(reps u v (xs@[x])) s1" "s = s1 + s2" "s1 ## s2" "one (1 + v) s2"
by (auto elim:sep_conjE)
from hh(1)[unfolded reps_rev[OF False]]
obtain s11 s12 s13 where hhh:
"(reps u (v - int (x + 1) - 1) xs) s11"
"(zero (v - int (x + 1))) s12" "(ones (v - int x) v) s13"
"s11 ## (s12 + s13)" "s12 ## s13" "s1 = s11 + s12 + s13"
apply (atomize_elim)
apply(elim sep_conjE)+
apply (rule_tac x = xa in exI)
apply (rule_tac x = xaa in exI)
apply (rule_tac x = ya in exI)
apply (intro conjI, assumption+)
by (auto simp:set_ins_def)
show ?thesis
proof(rule reps_splitedI[where v = "(v - int (x + 1) - 1)"])
show "(reps u (v - int (x + 1) - 1) xs \<and>* zero (v - int (x + 1) - 1 + 1) \<and>*
reps (v - int (x + 1) - 1 + 2) (1 + v) [Suc x]) s"
proof(rule sep_conjI)
from hhh(1) show "reps u (v - int (x + 1) - 1) xs s11" .
next
show "(zero (v - int (x + 1) - 1 + 1) \<and>* reps (v - int (x + 1) - 1 + 2) (1 + v) [Suc x]) (s12 + (s13 + s2))"
proof(rule sep_conjI)
from hhh(2) show "zero (v - int (x + 1) - 1 + 1) s12" by smt
next
from hh(4) hhh(3)
show "reps (v - int (x + 1) - 1 + 2) (1 + v) [Suc x] (s13 + s2)"
apply (simp add:reps.simps del:ones_simps add:ones_rev)
by (smt hh(3) hh(4) hhh(4) hhh(5) hhh(6) sep_add_disjD sep_conjI sep_disj_addI1)
next
show "s12 ## s13 + s2"
by (metis hh(3) hhh(4) hhh(5) hhh(6) sep_add_commute sep_add_disjD
sep_add_disjI2 sep_disj_addD sep_disj_addD1 sep_disj_addI1 sep_disj_commuteI)
next
show "s12 + (s13 + s2) = s12 + (s13 + s2)" by metis
qed
next
show "s11 ## s12 + (s13 + s2)"
by (metis hh(3) hhh(4) hhh(5) hhh(6) sep_disj_addD1 sep_disj_addI1 sep_disj_addI3)
next
show "s = s11 + (s12 + (s13 + s2))"
by (smt hh(2) hh(3) hhh(4) hhh(5) hhh(6) sep_add_assoc sep_add_commute
sep_add_disjD sep_add_disjI2 sep_disj_addD1 sep_disj_addD2
sep_disj_addI1 sep_disj_addI3 sep_disj_commuteI)
qed
next
from False show "xs \<noteq> []" .
next
show "[Suc x] \<noteq> []" by simp
qed
qed
lemma cond_expand: "(<cond> \<and>* p) s = (cond \<and> (p s))"
by (metis (full_types) condD pasrt_def sep_conj_commuteI
sep_conj_sep_emptyI sep_empty_def sep_globalise)
lemma ones_rev1:
assumes "\<not> (1 + n) < m"
shows "(ones m n \<and>* one (1 + n)) = (ones m (1 + n))"
by (insert ones_rev[OF assms, simplified], simp)
lemma reps_one_abs:
assumes "(reps u v [k] \<and>* one w) s"
"w = v + 1"
shows "(reps u w [Suc k]) s"
using assms unfolding assms
apply (simp add:reps.simps sep_conj_ac)
apply (subst (asm) sep_conj_cond)+
apply (erule condE, simp)
by (simp add:ones_rev sep_conj_ac, sep_cancel+, smt)
lemma reps'_reps_abs:
assumes "(reps' u v xs \<and>* reps w x ys) s"
"w = v + 1" "ys \<noteq> []"
shows "(reps u x (xs@ys)) s"
proof(cases "xs = []")
case False
with assms
have h: "splited (xs@ys) xs ys" by (simp add:splited_def)
from assms(1)[unfolded assms(2)]
show ?thesis
apply (unfold reps_splited[OF h])
apply (insert False, unfold reps'_def, simp)
apply (fwd reps_lenE, (subst (asm) sep_conj_cond)+)
by (erule condE, simp)
next
case True
with assms
show ?thesis
apply (simp add:reps'_def)
by (erule condE, simp)
qed
lemma reps_one_abs1:
assumes "(reps u v (xs@[k]) \<and>* one w) s"
"w = v + 1"
shows "(reps u w (xs@[Suc k])) s"
proof(cases "xs = []")
case True
with assms reps_one_abs
show ?thesis by simp
next
case False
hence "splited (xs@[k]) xs [k]" by (simp add:splited_def)
from assms(1)[unfolded reps_splited[OF this] assms(2)]
show ?thesis
apply (fwd reps_one_abs)
apply (fwd reps_reps'_abs)
apply (fwd reps'_reps_abs)
by (simp add:assms)
qed
lemma tm_hoare_inc00:
assumes h: "a < length ks \<and> ks ! a = v"
shows "\<lbrace>st i \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>* reps u ia ks \<and>* fam_conj {ia<..} zero\<rbrace>
i :[ Inc a ]: j
\<lbrace>st j \<and>*
ps u \<and>*
zero (u - 2) \<and>*
zero (u - 1) \<and>*
reps u (ia + int (reps_len (list_ext a ks)) - int (reps_len ks) + 1) (ks[a := Suc v]) \<and>*
fam_conj {(ia + int (reps_len (list_ext a ks)) - int (reps_len ks) + 1)<..} zero\<rbrace>"
(is "\<lbrace> ?P \<rbrace> ?code \<lbrace> ?Q \<rbrace>")
proof -
from h have "a < length ks" "ks ! a = v" by auto
from list_nth_expand[OF `a < length ks`]
have eq_ks: "ks = take a ks @ [ks!a] @ drop (Suc a) ks" .
from `a < length ks` have "ks \<noteq> []" by auto
hence "(reps u ia ks \<and>* zero (ia + 1)) = reps' u (ia + 1) ks"
by (simp add:reps'_def)
also from eq_ks have "\<dots> = reps' u (ia + 1) (take a ks @ [ks!a] @ drop (Suc a) ks)" by simp
also have "\<dots> = (EXS m. reps' u (m - 1) (take a ks) \<and>*
reps' m (ia + 1) (ks ! a # drop (Suc a) ks))"
by (simp add:reps'_append)
also have "\<dots> = (EXS m. reps' u (m - 1) (take a ks) \<and>*
reps' m (ia + 1) ([ks ! a] @ drop (Suc a) ks))"
by simp
also have "\<dots> = (EXS m ma. reps' u (m - 1) (take a ks) \<and>*
reps' m (ma - 1) [ks ! a] \<and>* reps' ma (ia + 1) (drop (Suc a) ks))"
by (simp only:reps'_append sep_conj_exists)
finally have eq_s: "(reps u ia ks \<and>* zero (ia + 1)) = \<dots>" .
{ fix m ma
have eq_u: "-1 + u = u - 1" by smt
have " \<lbrace>st i \<and>*
ps u \<and>*
zero (u - 2) \<and>*
zero (u - 1) \<and>*
(reps' u (m - 1) (take a ks) \<and>*
reps' m (ma - 1) [ks ! a] \<and>* reps' ma (ia + 1) (drop (Suc a) ks)) \<and>*
fam_conj {ia + 1<..} zero\<rbrace>
i :[ Inc a ]: j
\<lbrace>st j \<and>*
ps u \<and>*
zero (u - 2) \<and>*
zero (u - 1) \<and>*
reps u (ia + int (reps_len (list_ext a ks)) - int (reps_len ks) + 1) (ks[a := Suc v]) \<and>*
fam_conj {ia + int (reps_len (list_ext a ks)) - int (reps_len ks) + 1<..} zero\<rbrace>"
proof(cases "(drop (Suc a) ks) = []")
case True
{ fix hc
have eq_1: "(1 + (m + int (ks ! a))) = (m + int (ks ! a) + 1)" by simp
have eq_2: "take a ks @ [Suc (ks ! a)] = ks[a := Suc v]"
apply (subst (3) eq_ks, unfold True, simp)
by (metis True append_Nil2 eq_ks h upd_conv_take_nth_drop)
assume h: "(fam_conj {1 + (m + int (ks ! a))<..} zero \<and>*
reps u (1 + (m + int (ks ! a))) (take a ks @ [Suc (ks ! a)])) hc"
hence "(fam_conj {m + int (ks ! a) + 1<..} zero \<and>* reps u (m + int (ks ! a) + 1) (ks[a := Suc v])) hc"
by (unfold eq_1 eq_2 , sep_cancel+)
} note eq_fam = this
show ?thesis
apply (unfold Inc_def, subst (3) reps'_def, simp add:True sep_conj_cond)
apply (intro tm.pre_condI, simp)
apply (subst fam_conj_interv_simp, simp, subst (3) zero_def)
apply hsteps
apply (subst reps'_sg, simp add:sep_conj_cond del:ones_simps)
apply (rule tm.pre_condI, simp del:ones_simps)
apply hsteps
apply (rule_tac p = "
st j' \<and>* ps (1 + (m + int (ks ! a))) \<and>* zero (u - 1) \<and>* zero (u - 2) \<and>*
reps u (1 + (m + int (ks ! a))) (take a ks @ [Suc (ks!a)])
\<and>* fam_conj {1 + (m + int (ks ! a))<..} zero
" in tm.pre_stren)
apply (hsteps)
apply (simp add:sep_conj_ac list_ext_lt[OF `a < length ks`], sep_cancel+)
apply (fwd eq_fam, sep_cancel+)
apply (simp del:ones_simps add:sep_conj_ac)
apply (sep_cancel+, prune)
apply ((fwd abs_reps')+, simp)
apply (fwd reps_one_abs abs_reps')+
apply (subst (asm) reps'_def, simp)
by (subst fam_conj_interv_simp, simp add:sep_conj_ac)
next
case False
then obtain k' ks' where eq_drop: "drop (Suc a) ks = [k']@ks'"
by (metis append_Cons append_Nil list.exhaust)
from `a < length ks`
have eq_ks: "ks[a := Suc v] = (take a ks @ [Suc (ks ! a)]) @ (drop (Suc a) ks)"
apply (fold `ks!a = v`)
by (metis append_Cons append_Nil append_assoc upd_conv_take_nth_drop)
show ?thesis
apply (unfold Inc_def)
apply (unfold Inc_def eq_drop reps'_append, simp add:sep_conj_exists del:ones_simps)
apply (rule tm.precond_exI, subst (2) reps'_sg)
apply (subst sep_conj_cond)+
apply (subst (1) ones_int_expand)
apply (rule tm.pre_condI, simp del:ones_simps)
apply hsteps
(* apply (hsteps hoare_locate_skip_gen[OF `a < length ks`]) *)
apply (subst reps'_sg, simp add:sep_conj_cond del:ones_simps)
apply (rule tm.pre_condI, simp del:ones_simps)
apply hsteps
apply (rule_tac p = "st j' \<and>*
ps (2 + (m + int (ks ! a))) \<and>*
reps (2 + (m + int (ks ! a))) ia (drop (Suc a) ks) \<and>* zero (ia + 1) \<and>* zero (ia + 2) \<and>*
reps u (m + int (ks ! a)) (take a ks @ [ks!a]) \<and>* zero (1 + (m + int (ks ! a))) \<and>*
zero (u - 2) \<and>* zero (u - 1) \<and>* fam_conj {ia + 2<..} zero
" in tm.pre_stren)
apply (hsteps hoare_shift_right_cons_gen[OF False]
hoare_left_until_double_zero_gen[OF False])
apply (rule_tac p =
"st j' \<and>* ps (1 + (m + int (ks ! a))) \<and>*
zero (u - 2) \<and>* zero (u - 1) \<and>*
reps u (1 + (m + int (ks ! a))) (take a ks @ [Suc (ks ! a)]) \<and>*
zero (2 + (m + int (ks ! a))) \<and>*
reps (3 + (m + int (ks ! a))) (ia + 1) (drop (Suc a) ks) \<and>* fam_conj {ia + 1<..} zero
" in tm.pre_stren)
apply (hsteps)
apply (simp add:sep_conj_ac, sep_cancel+)
apply (unfold list_ext_lt[OF `a < length ks`], simp)
apply (fwd abs_reps')+
apply(fwd reps'_reps_abs)
apply (subst eq_ks, simp)
apply (sep_cancel+)
apply (thin_tac "mb = 4 + (m + (int (ks ! a) + int k'))")
apply (thin_tac "ma = 2 + (m + int (ks ! a))", prune)
apply (simp add: int_add_ac sep_conj_ac, sep_cancel+)
apply (fwd reps_one_abs1, subst fam_conj_interv_simp, simp, sep_cancel+, smt)
apply (fwd abs_ones)+
apply (fwd abs_reps')
apply (fwd abs_reps')
apply (fwd abs_reps')
apply (fwd abs_reps')
apply (unfold eq_drop, simp add:int_add_ac sep_conj_ac)
apply (sep_cancel+)
apply (fwd reps'_abs[where xs = "take a ks"])
apply (fwd reps'_abs[where xs = "[k']"])
apply (unfold reps'_def, simp add:int_add_ac sep_conj_ac)
apply (sep_cancel+)
by (subst (asm) fam_conj_interv_simp, simp, smt)
qed
} note h = this
show ?thesis
apply (subst fam_conj_interv_simp)
apply (rule_tac p = "st i \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>*
(reps u ia ks \<and>* zero (ia + 1)) \<and>* fam_conj {ia + 1<..} zero"
in tm.pre_stren)
apply (unfold eq_s, simp only:sep_conj_exists)
apply (intro tm.precond_exI h)
by (sep_cancel+, unfold eq_s, simp)
qed
declare ones_simps [simp del]
lemma tm_hoare_inc01:
assumes "length ks \<le> a \<and> v = 0"
shows
"\<lbrace>st i \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>* reps u ia ks \<and>* fam_conj {ia<..} zero\<rbrace>
i :[ Inc a ]: j
\<lbrace>st j \<and>*
ps u \<and>*
zero (u - 2) \<and>*
zero (u - 1) \<and>*
reps u (ia + int (reps_len (list_ext a ks)) - int (reps_len ks) + 1) ((list_ext a ks)[a := Suc v]) \<and>*
fam_conj {(ia + int (reps_len (list_ext a ks)) - int (reps_len ks) + 1)<..} zero\<rbrace>"
proof -
from assms have "length ks \<le> a" "v = 0" by auto
show ?thesis
apply (rule_tac p = "
st i \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>* (reps u ia ks \<and>* <(ia = u + int (reps_len ks) - 1)>) \<and>*
fam_conj {ia<..} zero
" in tm.pre_stren)
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, simp)
apply (unfold Inc_def)
apply hstep
(* apply (hstep hoare_locate_set_gen[OF `length ks \<le> a`]) *)
apply (simp only:sep_conj_exists)
apply (intro tm.precond_exI)
my_block
fix m w
have "reps m w [list_ext a ks ! a] =
(ones m (m + int (list_ext a ks ! a)) \<and>* <(w = m + int (list_ext a ks ! a))>)"
by (simp add:reps.simps)
my_block_end
apply (unfold this)
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, simp)
apply (subst fam_conj_interv_simp)
apply (hsteps)
apply (subst fam_conj_interv_simp, simp)
apply (hsteps)
apply (rule_tac p = "st j' \<and>* ps (m + int (list_ext a ks ! a) + 1) \<and>*
zero (u - 2) \<and>* zero (u - 1) \<and>*
reps u (m + int (list_ext a ks ! a) + 1)
((take a (list_ext a ks))@[Suc (list_ext a ks ! a)]) \<and>*
fam_conj {(m + int (list_ext a ks ! a) + 1)<..} zero
" in tm.pre_stren)
apply (hsteps)
apply (simp add:sep_conj_ac, sep_cancel+)
apply (unfold `v = 0`, prune)
my_block
from `length ks \<le> a` have "list_ext a ks ! a = 0"
by (metis le_refl list_ext_tail)
from `length ks \<le> a` have "a < length (list_ext a ks)"
by (metis list_ext_len)
from reps_len_suc[OF this]
have eq_len: "int (reps_len (list_ext a ks)) =
int (reps_len (list_ext a ks[a := Suc (list_ext a ks ! a)])) - 1"
by smt
fix m w hc
assume h: "(fam_conj {m + int (list_ext a ks ! a) + 1<..} zero \<and>*
reps u (m + int (list_ext a ks ! a) + 1) (take a (list_ext a ks) @ [Suc (list_ext a ks ! a)]))
hc"
then obtain s where
"(reps u (m + int (list_ext a ks ! a) + 1) (take a (list_ext a ks) @ [Suc (list_ext a ks ! a)])) s"
by (auto dest!:sep_conjD)
from reps_len_correct[OF this]
have "m = u + int (reps_len (take a (list_ext a ks) @ [Suc (list_ext a ks ! a)]))
- int (list_ext a ks ! a) - 2" by smt
from h [unfolded this]
have "(fam_conj {u + int (reps_len (list_ext a ks))<..} zero \<and>*
reps u (u + int (reps_len (list_ext a ks))) (list_ext a ks[a := Suc 0]))
hc"
apply (unfold eq_len, simp)
my_block
from `a < length (list_ext a ks)`
have "take a (list_ext a ks) @ [Suc (list_ext a ks ! a)] =
list_ext a ks[a := Suc (list_ext a ks ! a)]"
by (smt `list_ext a ks ! a = 0` assms length_take list_ext_tail_expand list_update_length)
my_block_end
apply (unfold this)
my_block
have "-1 + (u + int (reps_len (list_ext a ks[a := Suc (list_ext a ks ! a)]))) =
u + (int (reps_len (list_ext a ks[a := Suc (list_ext a ks ! a)])) - 1)" by simp
my_block_end
apply (unfold this)
apply (sep_cancel+)
by (unfold `(list_ext a ks ! a) = 0`, simp)
my_block_end
apply (rule this, assumption)
apply (simp only:sep_conj_ac, sep_cancel+)+
apply (fwd abs_reps')+
apply (fwd reps_one_abs)
apply (fwd reps'_reps_abs)
apply (simp add:int_add_ac sep_conj_ac)
apply (sep_cancel+)
apply (subst fam_conj_interv_simp, simp add:sep_conj_ac, smt)
apply (fwd reps_lenE, (subst (asm) sep_conj_cond)+, erule condE, simp)
by (sep_cancel+)
qed
definition "Dec a e = (TL continue.
(locate a;
if_reps_nz continue;
left_until_double_zero;
move_right;
move_right;
jmp e);
(TLabel continue;
right_until_zero;
move_left;
write_zero;
move_right;
move_right;
shift_left;
move_left;
move_left;
move_left;
left_until_double_zero;
move_right;
move_right))"
lemma cond_eq: "((<b> \<and>* p) s) = (b \<and> (p s))"
proof
assume "(<b> \<and>* p) s"
from condD[OF this] show " b \<and> p s" .
next
assume "b \<and> p s"
hence b and "p s" by auto
from `b` have "(<b>) 0" by (auto simp:pasrt_def)
moreover have "s = 0 + s" by auto
moreover have "0 ## s" by auto
moreover note `p s`
ultimately show "(<b> \<and>* p) s" by (auto intro!:sep_conjI)
qed
lemma tm_hoare_dec_fail00:
assumes "a < length ks \<and> ks ! a = 0"
shows "\<lbrace>st i \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>* reps u ia ks \<and>* fam_conj {ia<..} zero\<rbrace>
i :[ Dec a e ]: j
\<lbrace>st e \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>*
reps u (ia + int (reps_len (list_ext a ks)) - int (reps_len ks)) (list_ext a ks[a := 0]) \<and>*
fam_conj {ia + int (reps_len (list_ext a ks)) - int (reps_len ks) <..} zero\<rbrace>"
proof -
from assms have "a < length ks" "ks!a = 0" by auto
from list_nth_expand[OF `a < length ks`]
have eq_ks: "ks = take a ks @ [ks ! a] @ drop (Suc a) ks" .
show ?thesis
proof(cases " drop (Suc a) ks = []")
case False
then obtain k' ks' where eq_drop: "drop (Suc a) ks = [k']@ks'"
by (metis append_Cons append_Nil list.exhaust)
show ?thesis
apply (unfold Dec_def, intro t_hoare_local)
apply (subst tassemble_to.simps(2), rule tm.code_exI, rule tm.code_extension)
apply (subst (1) eq_ks)
my_block
have "(reps u ia (take a ks @ [ks ! a] @ drop (Suc a) ks) \<and>* fam_conj {ia<..} zero) =
(reps' u (ia + 1) ((take a ks @ [ks ! a]) @ drop (Suc a) ks) \<and>* fam_conj {ia + 1<..} zero)"
apply (subst fam_conj_interv_simp)
by (unfold reps'_def, simp add:sep_conj_ac)
my_block_end
apply (unfold this)
apply (subst reps'_append)
apply (unfold eq_drop)
apply (subst (2) reps'_append)
apply (simp only:sep_conj_exists, intro tm.precond_exI)
apply (subst (2) reps'_def, simp add:reps.simps ones_simps)
apply (subst reps'_append, simp only:sep_conj_exists, intro tm.precond_exI)
apply hstep
(* apply (hstep hoare_locate_skip_gen[OF `a < length ks`]) *)
my_block
fix m mb
have "(reps' mb (m - 1) [ks ! a]) = (reps mb (m - 2) [ks!a] \<and>* zero (m - 1))"
by (simp add:reps'_def, smt)
my_block_end
apply (unfold this)
apply hstep
(* apply (hstep hoare_if_reps_nz_false_gen[OF `ks!a = 0`]) *)
apply (simp only:reps.simps(2), simp add:`ks!a = 0`)
apply (rule_tac p = "st j'b \<and>*
ps mb \<and>*
reps u mb ((take a ks)@[ks ! a]) \<and>* <(m - 2 = mb)> \<and>*
zero (m - 1) \<and>*
zero (u - 1) \<and>*
one m \<and>*
zero (u - 2) \<and>*
ones (m + 1) (m + int k') \<and>*
<(-2 + ma = m + int k')> \<and>* zero (ma - 1) \<and>* reps' ma (ia + 1) ks' \<and>* fam_conj {ia + 1<..} zero"
in tm.pre_stren)
apply hsteps
apply (simp add:sep_conj_ac, sep_cancel+)
apply (subgoal_tac "m + int k' = ma - 2", simp)
apply (fwd abs_ones)+
apply (subst (asm) sep_conj_cond)+
apply (erule condE, auto)
apply (fwd abs_reps')+
apply (subgoal_tac "ma = m + int k' + 2", simp)
apply (fwd abs_reps')+
my_block
from `a < length ks`
have "list_ext a ks = ks" by (auto simp:list_ext_def)
my_block_end
apply (simp add:this)
apply (subst eq_ks, simp add:eq_drop `ks!a = 0`)
apply (subst (asm) reps'_def, simp)
apply (subst fam_conj_interv_simp, simp add:sep_conj_ac, sep_cancel+)
apply (metis append_Cons assms eq_Nil_appendI eq_drop eq_ks list_update_id)
apply (clarsimp)
apply (subst (asm) sep_conj_cond)+
apply (erule condE, clarsimp)
apply (subst (asm) sep_conj_cond)+
apply (erule condE, clarsimp)
apply (simp add:sep_conj_ac, sep_cancel+)
apply (fwd abs_reps')+
by (fwd reps'_reps_abs, simp add:`ks!a = 0`)
next
case True
show ?thesis
apply (unfold Dec_def, intro t_hoare_local)
apply (subst tassemble_to.simps(2), rule tm.code_exI, rule tm.code_extension)
apply (subst (1) eq_ks, unfold True, simp)
my_block
have "(reps u ia (take a ks @ [ks ! a]) \<and>* fam_conj {ia<..} zero) =
(reps' u (ia + 1) (take a ks @ [ks ! a]) \<and>* fam_conj {ia + 1<..} zero)"
apply (unfold reps'_def, subst fam_conj_interv_simp)
by (simp add:sep_conj_ac)
my_block_end
apply (subst (1) this)
apply (subst reps'_append)
apply (simp only:sep_conj_exists, intro tm.precond_exI)
apply (subst fam_conj_interv_simp, simp)
my_block
have "(zero (2 + ia)) = (tm (2 + ia) Bk)"
by (simp add:zero_def)
my_block_end my_note eq_z = this
apply hstep
(* apply (hstep hoare_locate_skip_gen[OF `a < length ks`]) *)
my_block
fix m
have "(reps' m (ia + 1) [ks ! a]) = (reps m ia [ks!a] \<and>* zero (ia + 1))"
by (simp add:reps'_def)
my_block_end
apply (unfold this, prune)
apply hstep
(* apply (hstep hoare_if_reps_nz_false_gen[OF `ks!a = 0`]) *)
apply (simp only:reps.simps(2), simp add:`ks!a = 0`)
apply (rule_tac p = "st j'b \<and>* ps m \<and>* (reps u m ((take a ks)@[ks!a]) \<and>* <(ia = m)>)
\<and>* zero (ia + 1) \<and>* zero (u - 1) \<and>*
zero (2 + ia) \<and>* zero (u - 2) \<and>* fam_conj {2 + ia<..} zero"
in tm.pre_stren)
apply hsteps
apply (simp add:sep_conj_ac)
apply ((subst (asm) sep_conj_cond)+, erule condE, simp)
my_block
from `a < length ks` have "list_ext a ks = ks" by (metis list_ext_lt)
my_block_end
apply (unfold this, simp)
apply (subst fam_conj_interv_simp)
apply (subst fam_conj_interv_simp, simp)
apply (simp only:sep_conj_ac, sep_cancel+)
apply (subst eq_ks, unfold True `ks!a = 0`, simp)
apply (metis True append_Nil2 assms eq_ks list_update_same_conv)
apply (simp add:sep_conj_ac)
apply (subst (asm) sep_conj_cond)+
apply (erule condE, simp, thin_tac "ia = m")
apply (fwd abs_reps')+
apply (simp add:sep_conj_ac int_add_ac, sep_cancel+)
apply (unfold reps'_def, simp)
by (metis sep.mult_commute)
qed
qed
lemma tm_hoare_dec_fail01:
assumes "length ks \<le> a"
shows "\<lbrace>st i \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>* reps u ia ks \<and>* fam_conj {ia<..} zero\<rbrace>
i :[ Dec a e ]: j
\<lbrace>st e \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>*
reps u (ia + int (reps_len (list_ext a ks)) - int (reps_len ks)) (list_ext a ks[a := 0]) \<and>*
fam_conj {ia + int (reps_len (list_ext a ks)) - int (reps_len ks) <..} zero\<rbrace>"
apply (unfold Dec_def, intro t_hoare_local)
apply (subst tassemble_to.simps(2), rule tm.code_exI, rule tm.code_extension)
apply (rule_tac p = "st i \<and>* ps u \<and>* zero (u - 2) \<and>*
zero (u - 1) \<and>* reps u ia ks \<and>* fam_conj {ia<..} zero \<and>*
<(ia = u + int (reps_len ks) - 1)>" in tm.pre_stren)
apply hstep
(* apply (hstep hoare_locate_set_gen[OF `length ks \<le> a`]) *)
apply (simp only:sep_conj_exists, intro tm.precond_exI)
my_block
from assms
have "list_ext a ks ! a = 0" by (metis le_refl list_ext_tail)
my_block_end my_note is_z = this
apply (subst fam_conj_interv_simp)
apply hstep
(* apply (hstep hoare_if_reps_nz_false_gen[OF is_z]) *)
apply (unfold is_z)
apply (subst (1) reps.simps)
apply (rule_tac p = "st j'b \<and>* ps m \<and>* reps u m (take a (list_ext a ks) @ [0]) \<and>* zero (w + 1) \<and>*
<(w = m + int 0)> \<and>* zero (u - 1) \<and>*
fam_conj {w + 1<..} zero \<and>* zero (u - 2) \<and>*
<(ia = u + int (reps_len ks) - 1)>" in tm.pre_stren)
my_block
have "(take a (list_ext a ks)) @ [0] \<noteq> []" by simp
my_block_end
apply hsteps
(* apply (hsteps hoare_left_until_double_zero_gen[OF this]) *)
apply (simp add:sep_conj_ac)
apply prune
apply (subst (asm) sep_conj_cond)+
apply (elim condE, simp add:sep_conj_ac, prune)
my_block
fix m w ha
assume h1: "w = m \<and> ia = u + int (reps_len ks) - 1"
and h: "(ps u \<and>*
st e \<and>*
zero (u - 1) \<and>*
zero (m + 1) \<and>*
fam_conj {m + 1<..} zero \<and>* zero (u - 2) \<and>* reps u m (take a (list_ext a ks) @ [0])) ha"
from h1 have eq_w: "w = m" and eq_ia: "ia = u + int (reps_len ks) - 1" by auto
from h obtain s' where "reps u m (take a (list_ext a ks) @ [0]) s'"
by (auto dest!:sep_conjD)
from reps_len_correct[OF this]
have eq_m: "m = u + int (reps_len (take a (list_ext a ks) @ [0])) - 1" .
from h[unfolded eq_m, simplified]
have "(ps u \<and>*
st e \<and>*
zero (u - 1) \<and>*
zero (u - 2) \<and>*
fam_conj {u + (-1 + int (reps_len (list_ext a ks)))<..} zero \<and>*
reps u (u + (-1 + int (reps_len (list_ext a ks)))) (list_ext a ks[a := 0])) ha"
apply (sep_cancel+)
apply (subst fam_conj_interv_simp, simp)
my_block
from `length ks \<le> a` have "list_ext a ks[a := 0] = list_ext a ks"
by (metis is_z list_update_id)
my_block_end
apply (unfold this)
my_block
from `length ks \<le> a` is_z
have "take a (list_ext a ks) @ [0] = list_ext a ks"
by (metis list_ext_tail_expand)
my_block_end
apply (unfold this)
by (simp add:sep_conj_ac, sep_cancel+, smt)
my_block_end
apply (rule this, assumption)
apply (sep_cancel+)[1]
apply (subst (asm) sep_conj_cond)+
apply (erule condE, prune, simp)
my_block
fix s m
assume "(reps' u (m - 1) (take a (list_ext a ks)) \<and>* ones m m \<and>* zero (m + 1)) s"
hence "reps' u (m + 1) (take a (list_ext a ks) @ [0]) s"
apply (unfold reps'_append)
apply (rule_tac x = m in EXS_intro)
by (subst (2) reps'_def, simp add:reps.simps)
my_block_end
apply (rotate_tac 1, fwd this)
apply (subst (asm) reps'_def, simp add:sep_conj_ac)
my_block
fix s
assume h: "(st i \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>*
reps u ia ks \<and>* fam_conj {ia<..} zero) s"
then obtain s' where "reps u ia ks s'" by (auto dest!:sep_conjD)
from reps_len_correct[OF this] have eq_ia: "ia = u + int (reps_len ks) - 1" .
from h
have "(st i \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>* reps u ia ks \<and>*
fam_conj {ia<..} zero \<and>* <(ia = u + int (reps_len ks) - 1)>) s"
by (unfold eq_ia, simp)
my_block_end
by (rule this, assumption)
lemma t_hoare_label1:
"(\<And>l. l = i \<Longrightarrow> \<lbrace>st l \<and>* p\<rbrace> l :[ c l ]: j \<lbrace>st k \<and>* q\<rbrace>) \<Longrightarrow>
\<lbrace>st l \<and>* p \<rbrace>
i:[(TLabel l; c l)]:j
\<lbrace>st k \<and>* q\<rbrace>"
by (unfold tassemble_to.simps, intro tm.code_exI tm.code_condI, clarify, auto)
lemma tm_hoare_dec_fail1:
assumes "a < length ks \<and> ks ! a = 0 \<or> length ks \<le> a"
shows "\<lbrace>st i \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>* reps u ia ks \<and>* fam_conj {ia<..} zero\<rbrace>
i :[ Dec a e ]: j
\<lbrace>st e \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>*
reps u (ia + int (reps_len (list_ext a ks)) - int (reps_len ks)) (list_ext a ks[a := 0]) \<and>*
fam_conj {ia + int (reps_len (list_ext a ks)) - int (reps_len ks) <..} zero\<rbrace>"
using assms
proof
assume "a < length ks \<and> ks ! a = 0"
thus ?thesis
by (rule tm_hoare_dec_fail00)
next
assume "length ks \<le> a"
thus ?thesis
by (rule tm_hoare_dec_fail01)
qed
lemma shift_left_nil_gen[step]:
assumes "u = v"
shows "\<lbrace>st i \<and>* ps u \<and>* zero v\<rbrace>
i :[shift_left]:j
\<lbrace>st j \<and>* ps u \<and>* zero v\<rbrace>"
apply(unfold assms shift_left_def, intro t_hoare_local t_hoare_label, clarify,
rule t_hoare_label_last, simp, clarify, prune, simp)
by hstep
lemma tm_hoare_dec_suc1:
assumes "a < length ks \<and> ks ! a = Suc v"
shows "\<lbrace>st i \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>* reps u ia ks \<and>* fam_conj {ia<..} zero\<rbrace>
i :[ Dec a e ]: j
\<lbrace>st j \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>*
reps u (ia - 1) (list_ext a ks[a := v]) \<and>*
fam_conj {ia - 1<..} zero\<rbrace>"
proof -
from assms have "a < length ks" " ks ! a = Suc v" by auto
from list_nth_expand[OF `a < length ks`]
have eq_ks: "ks = take a ks @ [ks ! a] @ drop (Suc a) ks" .
show ?thesis
proof(cases " drop (Suc a) ks = []")
case False
then obtain k' ks' where eq_drop: "drop (Suc a) ks = [k']@ks'"
by (metis append_Cons append_Nil list.exhaust)
show ?thesis
apply (unfold Dec_def, intro t_hoare_local)
apply (subst tassemble_to.simps(2), rule tm.code_exI)
apply (subst (1) eq_ks)
my_block
have "(reps u ia (take a ks @ [ks ! a] @ drop (Suc a) ks) \<and>* fam_conj {ia<..} zero) =
(reps' u (ia + 1) ((take a ks @ [ks ! a]) @ drop (Suc a) ks) \<and>* fam_conj {ia + 1<..} zero)"
apply (subst fam_conj_interv_simp)
by (unfold reps'_def, simp add:sep_conj_ac)
my_block_end
apply (unfold this)
apply (subst reps'_append)
apply (unfold eq_drop)
apply (subst (2) reps'_append)
apply (simp only:sep_conj_exists, intro tm.precond_exI)
apply (subst (2) reps'_def, simp add:reps.simps ones_simps)
apply (subst reps'_append, simp only:sep_conj_exists, intro tm.precond_exI)
apply (rule_tac q =
"st l \<and>*
ps mb \<and>*
zero (u - 1) \<and>*
reps' u (mb - 1) (take a ks) \<and>*
reps' mb (m - 1) [ks ! a] \<and>*
one m \<and>*
zero (u - 2) \<and>*
ones (m + 1) (m + int k') \<and>*
<(-2 + ma = m + int k')> \<and>* zero (ma - 1) \<and>* reps' ma (ia + 1) ks' \<and>* fam_conj {ia + 1<..} zero"
in tm.sequencing)
apply (rule tm.code_extension)
apply hstep
(* apply (hstep hoare_locate_skip_gen[OF `a < length ks`]) *)
apply (subst (2) reps'_def, simp)
my_block
fix i j l m mb
from `ks!a = (Suc v)` have "ks!a \<noteq> 0" by simp
from hoare_if_reps_nz_true[OF this, where u = mb and v = "m - 2"]
have "\<lbrace>st i \<and>* ps mb \<and>* reps mb (-2 + m) [ks ! a]\<rbrace>
i :[ if_reps_nz l ]: j
\<lbrace>st l \<and>* ps mb \<and>* reps mb (-2 + m) [ks ! a]\<rbrace>"
by smt
my_block_end
apply (hgoto this)
apply (simp add:sep_conj_ac, sep_cancel+)
apply (subst reps'_def, simp add:sep_conj_ac)
apply (rule tm.code_extension1)
apply (rule t_hoare_label1, simp, prune)
apply (subst (2) reps'_def, simp add:reps.simps)
apply (rule_tac p = "st j' \<and>* ps mb \<and>* zero (u - 1) \<and>* reps' u (mb - 1) (take a ks) \<and>*
((ones mb (mb + int (ks ! a)) \<and>* <(-2 + m = mb + int (ks ! a))>) \<and>* zero (mb + int (ks ! a) + 1)) \<and>*
one (mb + int (ks ! a) + 2) \<and>* zero (u - 2) \<and>*
ones (mb + int (ks ! a) + 3) (mb + int (ks ! a) + int k' + 2) \<and>*
<(-2 + ma = m + int k')> \<and>* zero (ma - 1) \<and>* reps' ma (ia + 1) ks' \<and>* fam_conj {ia + 1<..} zero
" in tm.pre_stren)
apply hsteps
(* apply (simp add:sep_conj_ac) *)
apply (unfold `ks!a = Suc v`)
my_block
fix mb
have "(ones mb (mb + int (Suc v))) = (ones mb (mb + int v) \<and>* one (mb + int (Suc v)))"
by (simp add:ones_rev)
my_block_end
apply (unfold this, prune)
apply hsteps
apply (rule_tac p = "st j'a \<and>*
ps (mb + int (Suc v) + 2) \<and>* zero (mb + int (Suc v) + 1) \<and>*
reps (mb + int (Suc v) + 2) ia (drop (Suc a) ks) \<and>* zero (ia + 1) \<and>* zero (ia + 2) \<and>*
zero (mb + int (Suc v)) \<and>*
ones mb (mb + int v) \<and>*
zero (u - 1) \<and>*
reps' u (mb - 1) (take a ks) \<and>*
zero (u - 2) \<and>* fam_conj {ia + 2<..} zero
" in tm.pre_stren)
apply hsteps
(* apply (hsteps hoare_shift_left_cons_gen[OF False]) *)
apply (rule_tac p = "st j'a \<and>* ps (ia - 1) \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>*
reps u (ia - 1) (take a ks @ [v] @ drop (Suc a) ks) \<and>*
zero ia \<and>* zero (ia + 1) \<and>* zero (ia + 2) \<and>*
fam_conj {ia + 2<..} zero
" in tm.pre_stren)
apply hsteps
apply (simp add:sep_conj_ac)
apply (subst fam_conj_interv_simp)
apply (subst fam_conj_interv_simp)
apply (subst fam_conj_interv_simp)
apply (simp add:sep_conj_ac)
apply (sep_cancel+)
my_block
have "take a ks @ v # drop (Suc a) ks = list_ext a ks[a := v]"
proof -
from `a < length ks` have "list_ext a ks = ks" by (metis list_ext_lt)
hence "list_ext a ks[a:=v] = ks[a:=v]" by simp
moreover from `a < length ks` have "ks[a:=v] = take a ks @ v # drop (Suc a) ks"
by (metis upd_conv_take_nth_drop)
ultimately show ?thesis by metis
qed
my_block_end
apply (unfold this, sep_cancel+, smt)
apply (simp add:sep_conj_ac)
apply (fwd abs_reps')+
apply (simp add:sep_conj_ac int_add_ac)
apply (sep_cancel+)
apply (subst (asm) reps'_def, simp add:sep_conj_ac)
apply (subst (asm) sep_conj_cond)+
apply (erule condE, clarsimp)
apply (simp add:sep_conj_ac, sep_cancel+)
apply (fwd abs_ones)+
apply (fwd abs_reps')+
apply (subst (asm) reps'_def, simp)
apply (subst (asm) fam_conj_interv_simp)
apply (simp add:sep_conj_ac int_add_ac eq_drop reps'_def)
apply (subst (asm) sep_conj_cond)+
apply (erule condE, clarsimp)
by (simp add:sep_conj_ac int_add_ac)
next
case True
show ?thesis
apply (unfold Dec_def, intro t_hoare_local)
apply (subst tassemble_to.simps(2), rule tm.code_exI)
apply (subst (1) eq_ks, simp add:True)
my_block
have "(reps u ia (take a ks @ [ks ! a]) \<and>* fam_conj {ia<..} zero) =
(reps' u (ia + 1) (take a ks @ [ks ! a]) \<and>* fam_conj {ia + 1<..} zero)"
apply (subst fam_conj_interv_simp)
by (unfold reps'_def, simp add:sep_conj_ac)
my_block_end
apply (unfold this)
apply (subst reps'_append)
apply (simp only:sep_conj_exists, intro tm.precond_exI)
apply (rule_tac q = "st l \<and>* ps m \<and>* zero (u - 1) \<and>* reps' u (m - 1) (take a ks) \<and>*
reps' m (ia + 1) [ks ! a] \<and>* zero (2 + ia) \<and>* zero (u - 2) \<and>* fam_conj {2 + ia<..} zero"
in tm.sequencing)
apply (rule tm.code_extension)
apply (subst fam_conj_interv_simp, simp)
apply hsteps
(* apply (hstep hoare_locate_skip_gen[OF `a < length ks`]) *)
my_block
fix m
have "(reps' m (ia + 1) [ks ! a]) =
(reps m ia [ks!a] \<and>* zero (ia + 1))"
by (unfold reps'_def, simp)
my_block_end
apply (unfold this)
my_block
fix i j l m
from `ks!a = (Suc v)` have "ks!a \<noteq> 0" by simp
my_block_end
apply (hgoto hoare_if_reps_nz_true_gen)
apply (rule tm.code_extension1)
apply (rule t_hoare_label1, simp)
apply (thin_tac "la = j'", prune)
apply (subst (1) reps.simps)
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, simp)
apply hsteps
apply (unfold `ks!a = Suc v`)
my_block
fix m
have "(ones m (m + int (Suc v))) = (ones m (m + int v) \<and>* one (m + int (Suc v)))"
by (simp add:ones_rev)
my_block_end
apply (unfold this)
apply hsteps
apply (rule_tac p = "st j'a \<and>* ps (m + int v) \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>*
reps u (m + int v) (take a ks @ [v]) \<and>* zero (m + (1 + int v)) \<and>*
zero (2 + (m + int v)) \<and>* zero (3 + (m + int v)) \<and>*
fam_conj {3 + (m + int v)<..} zero
" in tm.pre_stren)
apply hsteps
apply (simp add:sep_conj_ac, sep_cancel+)
my_block
have "take a ks @ [v] = list_ext a ks[a := v]"
proof -
from True `a < length ks` have "ks = take a ks @ [ks!a]"
by (metis append_Nil2 eq_ks)
hence "ks[a:=v] = take a ks @ [v]"
by (metis True `a < length ks` upd_conv_take_nth_drop)
moreover from `a < length ks` have "list_ext a ks = ks"
by (metis list_ext_lt)
ultimately show ?thesis by simp
qed
my_block_end my_note eq_l = this
apply (unfold this)
apply (subst fam_conj_interv_simp)
apply (subst fam_conj_interv_simp)
apply (subst fam_conj_interv_simp)
apply (simp add:sep_conj_ac, sep_cancel, smt)
apply (simp add:sep_conj_ac int_add_ac)+
apply (sep_cancel+)
apply (fwd abs_reps')+
apply (fwd reps'_reps_abs)
by (simp add:eq_l)
qed
qed
definition "cfill_until_one = (TL start exit.
TLabel start;
if_one exit;
write_one;
move_left;
jmp start;
TLabel exit
)"
lemma hoare_cfill_until_one:
"\<lbrace>st i \<and>* ps v \<and>* one (u - 1) \<and>* zeros u v\<rbrace>
i :[ cfill_until_one ]: j
\<lbrace>st j \<and>* ps (u - 1) \<and>* ones (u - 1) v \<rbrace>"
proof(induct u v rule:zeros_rev_induct)
case (Base x y)
thus ?case
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, simp add:ones_simps)
apply (unfold cfill_until_one_def, intro t_hoare_local t_hoare_label, rule t_hoare_label_last, simp+)
by hstep
next
case (Step x y)
show ?case
apply (rule_tac q = "st i \<and>* ps (y - 1) \<and>* one (x - 1) \<and>* zeros x (y - 1) \<and>* one y" in tm.sequencing)
apply (subst cfill_until_one_def, intro t_hoare_local t_hoare_label, rule t_hoare_label_last, simp+)
apply hsteps
my_block
fix i j l
have "\<lbrace>st i \<and>* ps (y - 1) \<and>* one (x - 1) \<and>* zeros x (y - 1)\<rbrace>
i :[ jmp l ]: j
\<lbrace>st l \<and>* ps (y - 1) \<and>* one (x - 1) \<and>* zeros x (y - 1)\<rbrace>"
apply (case_tac "(y - 1) < x", simp add:zeros_simps)
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, simp)
apply hstep
apply (drule_tac zeros_rev, simp)
by hstep
my_block_end
apply (hstep this)
(* The next half *)
apply (hstep Step(2), simp add:sep_conj_ac, sep_cancel+)
by (insert Step(1), simp add:ones_rev sep_conj_ac)
qed
definition "cmove = (TL start exit.
TLabel start;
left_until_zero;
left_until_one;
move_left;
if_zero exit;
move_right;
write_zero;
right_until_one;
right_until_zero;
write_one;
jmp start;
TLabel exit
)"
declare zeros.simps [simp del] zeros_simps[simp del]
lemma hoare_cmove:
assumes "w \<le> k"
shows "\<lbrace>st i \<and>* ps (v + 2 + int w) \<and>* zero (u - 1) \<and>*
reps u (v - int w) [k - w] \<and>* zeros (v - int w + 1) (v + 1) \<and>*
one (v + 2) \<and>* ones (v + 3) (v + 2 + int w) \<and>* zeros (v + 3 + int w) (v + int(reps_len [k]) + 1)\<rbrace>
i :[cmove]: j
\<lbrace>st j \<and>* ps (u - 1) \<and>* zero (u - 1) \<and>* reps u u [0] \<and>* zeros (u + 1) (v + 1) \<and>*
reps (v + 2) (v + int (reps_len [k]) + 1) [k]\<rbrace>"
using assms
proof(induct "k - w" arbitrary: w)
case (0 w)
hence "w = k" by auto
show ?case
apply (simp add: `w = k` del:zeros.simps zeros_simps)
apply (unfold cmove_def, intro t_hoare_local t_hoare_label, rule t_hoare_label_last, simp+)
apply (simp add:reps_len_def reps_sep_len_def reps_ctnt_len_def del:zeros_simps zeros.simps)
apply (rule_tac p = "st i \<and>* ps (v + 2 + int k) \<and>* zero (u - 1) \<and>*
reps u u [0] \<and>* zeros (u + 1) (v + 1) \<and>*
ones (v + 2) (v + 2 + int k) \<and>* zeros (v + 3 + int k) (2 + (v + int k)) \<and>*
<(u = v - int k)>"
in tm.pre_stren)
my_block
fix i j
have "\<lbrace>st i \<and>* ps (v + 2 + int k) \<and>* zeros (u + 1) (v + 1) \<and>* ones (v + 2) (v + 2 + int k)
\<and>* <(u = v - int k)>\<rbrace>
i :[ left_until_zero ]: j
\<lbrace>st j \<and>* ps (v + 1) \<and>* zeros (u + 1) (v + 1) \<and>* ones (v + 2) (v + 2 + int k)
\<and>* <(u = v - int k)>\<rbrace>"
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, simp)
my_block
have "(zeros (v - int k + 1) (v + 1)) = (zeros (v - int k + 1) v \<and>* zero (v + 1))"
by (simp only:zeros_rev, smt)
my_block_end
apply (unfold this)
by hsteps
my_block_end
apply (hstep this)
my_block
fix i j
have "\<lbrace>st i \<and>* ps (v + 1) \<and>* reps u u [0] \<and>* zeros (u + 1) (v + 1)\<rbrace>
i :[left_until_one]:j
\<lbrace>st j \<and>* ps u \<and>* reps u u [0] \<and>* zeros (u + 1) (v + 1)\<rbrace>"
apply (simp add:reps.simps ones_simps)
by hsteps
my_block_end
apply (hsteps this)
apply ((subst (asm) sep_conj_cond)+, erule condE, clarsimp)
apply (fwd abs_reps')+
apply (simp only:sep_conj_ac int_add_ac, sep_cancel+)
apply (simp add:int_add_ac sep_conj_ac zeros_simps)
apply (simp add:sep_conj_ac int_add_ac, sep_cancel+)
apply (fwd reps_lenE)
apply (subst (asm) sep_conj_cond)+
apply (erule condE, clarsimp)
apply (subgoal_tac "v = u + int k + int (reps_len [0]) - 1", clarsimp)
apply (simp add:reps_len_sg)
apply (fwd abs_ones)+
apply (fwd abs_reps')+
apply (simp add:sep_conj_ac int_add_ac)
apply (sep_cancel+)
apply (simp add:reps.simps, smt)
by (clarsimp)
next
case (Suc k' w)
from `Suc k' = k - w` `w \<le> k`
have h: "k' = k - (Suc w)" "Suc w \<le> k" by auto
show ?case
apply (rule tm.sequencing[OF _ Suc(1)[OF h(1, 2)]])
apply (unfold cmove_def, intro t_hoare_local t_hoare_label, rule t_hoare_label_last, simp+)
apply (simp add:reps_len_def reps_sep_len_def reps_ctnt_len_def del:zeros_simps zeros.simps)
my_block
fix i j
have "\<lbrace>st i \<and>* ps (v + 2 + int w) \<and>* zeros (v - int w + 1) (v + 1) \<and>*
one (v + 2) \<and>* ones (v + 3) (v + 2 + int w) \<rbrace>
i :[left_until_zero]: j
\<lbrace>st j \<and>* ps (v + 1) \<and>* zeros (v - int w + 1) (v + 1) \<and>*
one (v + 2) \<and>* ones (v + 3) (v + 2 + int w) \<rbrace>"
my_block
have "(one (v + 2) \<and>* ones (v + 3) (v + 2 + int w)) =
ones (v + 2) (v + 2 + int w)"
by (simp only:ones_simps, smt)
my_block_end
apply (unfold this)
my_block
have "(zeros (v - int w + 1) (v + 1)) = (zeros (v - int w + 1) v \<and>* zero (v + 1))"
by (simp only:zeros_rev, simp)
my_block_end
apply (unfold this)
by hsteps
my_block_end
apply (hstep this)
my_block
fix i j
have "\<lbrace>st i \<and>* ps (v + 1) \<and>* reps u (v - int w) [k - w] \<and>* zeros (v - int w + 1) (v + 1)\<rbrace>
i :[left_until_one]: j
\<lbrace>st j \<and>* ps (v - int w) \<and>* reps u (v - int w) [k - w] \<and>* zeros (v - int w + 1) (v + 1)\<rbrace>"
apply (simp add:reps.simps ones_rev)
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, clarsimp)
apply (subgoal_tac "u + int (k - w) = v - int w", simp)
defer
apply simp
by hsteps
my_block_end
apply (hstep this)
my_block
have "(reps u (v - int w) [k - w]) = (reps u (v - (1 + int w)) [k - Suc w] \<and>* one (v - int w))"
apply (subst (1 2) reps.simps)
apply (subst sep_conj_cond)+
my_block
have "((v - int w = u + int (k - w))) =
(v - (1 + int w) = u + int (k - Suc w))"
apply auto
apply (smt Suc.prems h(2))
by (smt Suc.prems h(2))
my_block_end
apply (simp add:this)
my_block
fix b p q
assume "(b \<Longrightarrow> (p::tassert) = q)"
have "(<b> \<and>* p) = (<b> \<and>* q)"
by (metis `b \<Longrightarrow> p = q` cond_eqI)
my_block_end
apply (rule this)
my_block
assume "v - (1 + int w) = u + int (k - Suc w)"
hence "v = 1 + int w + u + int (k - Suc w)" by auto
my_block_end
apply (simp add:this)
my_block
have "\<not> (u + int (k - w)) < u" by auto
my_block_end
apply (unfold ones_rev[OF this])
my_block
from Suc (2, 3) have "(u + int (k - w) - 1) = (u + int (k - Suc w))"
by auto
my_block_end
apply (unfold this)
my_block
from Suc (2, 3) have "(u + int (k - w)) = (1 + (u + int (k - Suc w)))"
by auto
my_block_end
by (unfold this, simp)
my_block_end
apply (unfold this)
my_block
fix i j
have "\<lbrace>st i \<and>* ps (v - int w) \<and>*
(reps u (v - (1 + int w)) [k - Suc w] \<and>* one (v - int w))\<rbrace>
i :[ move_left]: j
\<lbrace>st j \<and>* ps (v - (1 + int w)) \<and>*
(reps u (v - (1 + int w)) [k - Suc w] \<and>* one (v - int w))\<rbrace>"
apply (simp add:reps.simps ones_rev)
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, clarsimp)
apply (subgoal_tac " u + int (k - Suc w) = v - (1 + int w)", simp)
defer
apply simp
apply hsteps
by (simp add:sep_conj_ac, sep_cancel+, smt)
my_block_end
apply (hstep this)
my_block
fix i' j'
have "\<lbrace>st i' \<and>* ps (v - (1 + int w)) \<and>* reps u (v - (1 + int w)) [k - Suc w]\<rbrace>
i' :[ if_zero j ]: j'
\<lbrace>st j' \<and>* ps (v - (1 + int w)) \<and>* reps u (v - (1 + int w)) [k - Suc w]\<rbrace>"
apply (simp add:reps.simps ones_rev)
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, clarsimp)
apply (subgoal_tac " u + int (k - Suc w) = v - (1 + int w)", simp)
defer
apply simp
by hstep
my_block_end
apply (hstep this)
my_block
fix i j
have "\<lbrace>st i \<and>* ps (v - (1 + int w)) \<and>* reps u (v - (1 + int w)) [k - Suc w]\<rbrace>
i :[ move_right ]: j
\<lbrace>st j \<and>* ps (v - int w) \<and>* reps u (v - (1 + int w)) [k - Suc w] \<rbrace>"
apply (simp add:reps.simps ones_rev)
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, clarsimp)
apply (subgoal_tac " u + int (k - Suc w) = v - (1 + int w)", simp)
defer
apply simp
by hstep
my_block_end
apply (hsteps this)
my_block
fix i j
have "\<lbrace>st i \<and>* ps (v - int w) \<and>* one (v + 2) \<and>*
zero (v - int w) \<and>* zeros (v - int w + 1) (v + 1)\<rbrace>
i :[right_until_one]: j
\<lbrace>st j \<and>* ps (v + 2) \<and>* one (v + 2) \<and>* zero (v - int w) \<and>* zeros (v - int w + 1) (v + 1)\<rbrace>"
my_block
have "(zero (v - int w) \<and>* zeros (v - int w + 1) (v + 1)) =
(zeros (v - int w) (v + 1))"
by (simp add:zeros_simps)
my_block_end
apply (unfold this)
by hsteps
my_block_end
apply (hstep this)
my_block
from Suc(2, 3) have "w < k" by auto
hence "(zeros (v + 3 + int w) (2 + (v + int k))) =
(zero (v + 3 + int w) \<and>* zeros (4 + (v + int w)) (2 + (v + int k)))"
by (simp add:zeros_simps)
my_block_end
apply (unfold this)
my_block
fix i j
have "\<lbrace>st i \<and>* ps (v + 2) \<and>* zero (v + 3 + int w) \<and>* zeros (4 + (v + int w)) (2 + (v + int k)) \<and>*
one (v + 2) \<and>* ones (v + 3) (v + 2 + int w)\<rbrace>
i :[right_until_zero]: j
\<lbrace>st j \<and>* ps (v + 3 + int w) \<and>* zero (v + 3 + int w) \<and>* zeros (4 + (v + int w)) (2 + (v + int k)) \<and>*
one (v + 2) \<and>* ones (v + 3) (v + 2 + int w)\<rbrace>"
my_block
have "(one (v + 2) \<and>* ones (v + 3) (v + 2 + int w)) =
(ones (v + 2) (v + 2 + int w))"
by (simp add:ones_simps, smt)
my_block_end
apply (unfold this)
by hsteps
my_block_end
apply (hsteps this, simp only:sep_conj_ac)
apply (sep_cancel+, simp add:sep_conj_ac)
my_block
fix s
assume "(zero (v - int w) \<and>* zeros (v - int w + 1) (v + 1)) s"
hence "zeros (v - int w) (v + 1) s"
by (simp add:zeros_simps)
my_block_end
apply (fwd this)
my_block
fix s
assume "(one (v + 3 + int w) \<and>* ones (v + 3) (v + 2 + int w)) s"
hence "ones (v + 3) (3 + (v + int w)) s"
by (simp add:ones_rev sep_conj_ac, smt)
my_block_end
apply (fwd this)
by (simp add:sep_conj_ac, smt)
qed
definition "cinit = (right_until_zero; move_right; write_one)"
definition "copy = (cinit; cmove; move_right; move_right; right_until_one; move_left; move_left; cfill_until_one)"
lemma hoare_copy:
shows
"\<lbrace>st i \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>* reps u v [k] \<and>* zero (v + 1) \<and>*
zeros (v + 2) (v + int(reps_len [k]) + 1)\<rbrace>
i :[copy]: j
\<lbrace>st j \<and>* ps u \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>* reps u v [k] \<and>* zero (v + 1) \<and>*
reps (v + 2) (v + int (reps_len [k]) + 1) [k]\<rbrace>"
apply (unfold copy_def)
my_block
fix i j
have
"\<lbrace>st i \<and>* ps u \<and>* reps u v [k] \<and>* zero (v + 1) \<and>* zeros (v + 2) (v + int(reps_len [k]) + 1)\<rbrace>
i :[cinit]: j
\<lbrace>st j \<and>* ps (v + 2) \<and>* reps u v [k] \<and>* zero (v + 1) \<and>*
one (v + 2) \<and>* zeros (v + 3) (v + int(reps_len [k]) + 1)\<rbrace>"
apply (unfold cinit_def)
apply (simp add:reps.simps)
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, simp)
apply hsteps
apply (simp add:sep_conj_ac)
my_block
have "(zeros (u + int k + 2) (u + int k + int (reps_len [k]) + 1)) =
(zero (u + int k + 2) \<and>* zeros (u + int k + 3) (u + int k + int (reps_len [k]) + 1))"
by (smt reps_len_sg zeros_step_simp)
my_block_end
apply (unfold this)
apply hstep
by (simp add:sep_conj_ac, sep_cancel+, smt)
my_block_end
apply (hstep this)
apply (rule_tac p = "st j' \<and>* ps (v + 2) \<and>* reps u v [k] \<and>* zero (v + 1) \<and>*
one (v + 2) \<and>* zeros (v + 3) (v + int (reps_len [k]) + 1) \<and>* zero (u - 2) \<and>* zero (u - 1) \<and>*
<(v = u + int (reps_len [k]) - 1)>
" in tm.pre_stren)
my_block
fix i j
from hoare_cmove[where w = 0 and k = k and i = i and j = j and v = v and u = u]
have "\<lbrace>st i \<and>* ps (v + 2) \<and>* zero (u - 1) \<and>* reps u v [k] \<and>* zero (v + 1) \<and>*
one (v + 2) \<and>* zeros (v + 3) (v + int(reps_len [k]) + 1)\<rbrace>
i :[cmove]: j
\<lbrace>st j \<and>* ps (u - 1) \<and>* zero (u - 1) \<and>* reps u u [0] \<and>* zeros (u + 1) (v + 1) \<and>*
reps (v + 2) (v + int (reps_len [k]) + 1) [k]\<rbrace>"
by (auto simp:ones_simps zeros_simps)
my_block_end
apply (hstep this)
apply (hstep, simp)
my_block
have "reps u u [0] = one u" by (simp add:reps.simps ones_simps)
my_block_end my_note eq_repsz = this
apply (unfold this)
apply (hstep)
apply (subst reps.simps, simp add: ones_simps)
apply hsteps
apply (subst sep_conj_cond)+
apply (rule tm.pre_condI, simp del:zeros.simps zeros_simps)
apply (thin_tac "int (reps_len [k]) = 1 + int k \<and> v = u + int (reps_len [k]) - 1")
my_block
have "(zeros (u + 1) (u + int k + 1)) = (zeros (u + 1) (u + int k) \<and>* zero (u + int k + 1))"
by (simp only:zeros_rev, smt)
my_block_end
apply (unfold this)
apply (hstep, simp)
my_block
fix i j
from hoare_cfill_until_one[where v = "u + int k" and u = "u + 1"]
have "\<lbrace>st i \<and>* ps (u + int k) \<and>* one u \<and>* zeros (u + 1) (u + int k)\<rbrace>
i :[ cfill_until_one ]: j
\<lbrace>st j \<and>* ps u \<and>* ones u (u + int k) \<rbrace>"
by simp
my_block_end
apply (hstep this, simp add:sep_conj_ac reps.simps ones_simps)
apply (simp add:sep_conj_ac reps.simps ones_simps)
apply (subst sep_conj_cond)+
apply (subst (asm) sep_conj_cond)+
apply (rule condI)
apply (erule condE, simp)
apply (simp add: reps_len_def reps_sep_len_def reps_ctnt_len_def)
apply (sep_cancel+)
by (erule condE, simp)
end