(* * Vericert: Verified high-level synthesis. * Copyright (C) 2020 Yann Herklotz <yann@yannherklotz.com> * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see <https://www.gnu.org/licenses/>. *) Require Import Coqlib Maps. Require Import AST Integers Values Events Memory Globalenvs Smallstep. Require Import Op Registers. Definition node := positive. Inductive instruction : Type := | RBnop : instruction | RBop : operation -> list reg -> reg -> instruction | RBload : memory_chunk -> addressing -> list reg -> reg -> instruction | RBstore : memory_chunk -> addressing -> list reg -> reg -> instruction. Definition bblock_body : Type := list instruction. Inductive control_flow_inst : Type := | RBcall : signature -> reg + ident -> list reg -> reg -> node -> control_flow_inst | RBtailcall : signature -> reg + ident -> list reg -> control_flow_inst | RBbuiltin : external_function -> list (builtin_arg reg) -> builtin_res reg -> node -> control_flow_inst | RBcond : condition -> list reg -> node -> node -> control_flow_inst | RBjumptable : reg -> list node -> control_flow_inst | RBreturn : option reg -> control_flow_inst | RBgoto : node -> control_flow_inst. Record bblock : Type := mk_bblock { bb_body: bblock_body; bb_exit: option control_flow_inst }. Definition code : Type := PTree.t bblock. Record function: Type := mkfunction { fn_sig: signature; fn_params: list reg; fn_stacksize: Z; fn_code: code; fn_entrypoint: node }. Definition fundef := AST.fundef function. Definition program := AST.program fundef unit. Definition funsig (fd: fundef) := match fd with | Internal f => fn_sig f | External ef => ef_sig ef end. Definition successors_instr (i : control_flow_inst) : list node := match i with | RBcall sig ros args res s => s :: nil | RBtailcall sig ros args => nil | RBbuiltin ef args res s => s :: nil | RBcond cond args ifso ifnot => ifso :: ifnot :: nil | RBjumptable arg tbl => tbl | RBreturn optarg => nil | RBgoto n => n :: nil end. (* Definition genv := Genv.t fundef unit. Definition regset := Regmap.t val. Fixpoint init_regs (vl: list val) (rl: list reg) {struct rl} : regset := match rl, vl with | r1 :: rs, v1 :: vs => Regmap.set r1 v1 (init_regs vs rs) | _, _ => Regmap.init Vundef end. Inductive stackframe : Type := | Stackframe: forall (res: reg) (**r where to store the result *) (f: function) (**r calling function *) (sp: val) (**r stack pointer in calling function *) (pc: node) (**r program point in calling function *) (rs: regset), (**r register state in calling function *) stackframe. Inductive cont : Type := | C | N. Inductive state : Type := | State: forall (stack: list stackframe) (**r call stack *) (f: function) (**r current function *) (sp: val) (**r stack pointer *) (pc: node) (**r current program point in [c] *) (rs: regset) (**r register state *) (m: mem) (**r memory state *) (bblock: bblock) (**r bblock being executed *) (c : cont), state | Callstate: forall (stack: list stackframe) (**r call stack *) (f: fundef) (**r function to call *) (args: list val) (**r arguments to the call *) (m: mem), (**r memory state *) state | Returnstate: forall (stack: list stackframe) (**r call stack *) (v: val) (**r return value for the call *) (m: mem), (**r memory state *) state. Section RELSEM. Variable ge: genv. Definition find_function (ros: reg + ident) (rs: regset) : option fundef := match ros with | inl r => Genv.find_funct ge rs#r | inr symb => match Genv.find_symbol ge symb with | None => None | Some b => Genv.find_funct_ptr ge b end end. Inductive step : state -> trace -> state -> Prop := | exec_RBnop : forall s f sp pc rs m ls ci, step (State s f sp pc rs m (mk_bblock (RBnop :: ls) ci) C) E0 (State s f sp (Pos.succ pc) rs m (mk_bblock ls ci) C) | exec_RBop : forall s f sp pc rs m ls args op res ci v, eval_operation ge sp op rs##args m = Some v -> step (State s f sp pc rs m (mk_bblock (RBop op args res :: ls) ci) C) E0 (State s f sp (Pos.succ pc) rs m (mk_bblock ls ci) C) | exec_RBload: forall s f sp pc rs m chunk addr args dst a v ls ci, eval_addressing ge sp addr rs##args = Some a -> Mem.loadv chunk m a = Some v -> step (State s f sp pc rs m (mk_bblock (RBload chunk addr args dst :: ls) ci) C) E0 (State s f sp (Pos.succ pc) (rs#dst <- v) m (mk_bblock ls ci) C) | exec_RBstore: forall s f sp pc rs m chunk addr args src a m' ls ci, eval_addressing ge sp addr rs##args = Some a -> Mem.storev chunk m a rs#src = Some m' -> step (State s f sp pc rs m (mk_bblock (RBstore chunk addr args src :: ls) ci) C) E0 (State s f sp (Pos.succ pc) rs m' (mk_bblock ls ci) C) | exec_RBcond: forall s f sp pc rs m cond args ifso ifnot b pc', eval_condition cond rs##args m = Some b -> pc' = (if b then ifso else ifnot) -> step (State s f sp pc rs m (mk_bblock nil (RBcond cond args ifso ifnot)) C) E0 (State s f sp pc' rs m (mk_bblock nil (RBcond cond args ifso ifnot)) N) . End RELSEM. *)