X-Git-Url: http://matita.cs.unibo.it/gitweb/?a=blobdiff_plain;f=helm%2Fsoftware%2Fmatita%2Fcontribs%2Fassembly%2Fcompiler%2Fpreast_to_ast.ma;h=d129991687ec5a66ec9b0971834937a748a79b76;hb=34e2c8f59dd7924e15a7746644182d12ad09fed3;hp=49fabf83edc7fbbf1f150551f2c95ade873f0e4a;hpb=4924f99796029eecb58e920ca7a6a366efe2373e;p=helm.git diff --git a/helm/software/matita/contribs/assembly/compiler/preast_to_ast.ma b/helm/software/matita/contribs/assembly/compiler/preast_to_ast.ma index 49fabf83e..d12999168 100755 --- a/helm/software/matita/contribs/assembly/compiler/preast_to_ast.ma +++ b/helm/software/matita/contribs/assembly/compiler/preast_to_ast.ma @@ -27,16 +27,67 @@ include "compiler/sigma.ma". (* PASSO 1 : da PREAST a AST *) (* ************************* *) -lemma pippo : ∀t1,t2:ast_base_type. - (eq_ast_base_type t1 t2 = true) → (t1 = t2). - unfold eq_ast_base_type; - intros; - elim t1 in H:(%); - elim t2 in H:(%); - normalize in H:(%); - try reflexivity; - destruct H; -qed. +(* NB: ASSERTO + al parser spetta il compito di rigettare le condizioni statiche verificabili + - divisione per valore 0 + al parser spetta il compito di collassare le espressioni statiche + - val1+val2 -> val3, ... + al parser spetta il compito di collassare gli statement con condizioni statiche + - if(true) { b1 } else { b2 } -> b1, ... + al parser spetta il compito di individuare divergenza e dead code + - while(true) { b1 } -> loop infinito, ... +*) + +(* operatore di cast *) +definition preast_to_ast_expr_check ≝ +λd.λe:aux_env_type d.λsig:(Σt'.ast_expr d e t').λt:ast_type. + match sig with [ sigma_intro t' expr ⇒ + match eq_ast_type t' t + return λx.eq_ast_type t' t = x → option (ast_expr d e t) + with + [ true ⇒ λp:(eq_ast_type t' t = true).Some ? (eq_rect ? t' (λt.ast_expr d e t) expr t (eqasttype_to_eq ?? p)) + | false ⇒ λp:(eq_ast_type t' t = false).None ? + ] (refl_eq ? (eq_ast_type t' t)) + ]. + +definition preast_to_ast_init_check ≝ +λd.λe:aux_env_type d.λsig:Σt'.ast_init d e t'.λt:ast_type. + match sig with [ sigma_intro t' expr ⇒ + match eq_ast_type t' t + return λx.eq_ast_type t' t = x → option (ast_init d e t) + with + [ true ⇒ λp:(eq_ast_type t' t = true).Some ? (eq_rect ? t' (λt.ast_init d e t) expr t (eqasttype_to_eq ?? p)) + | false ⇒ λp:(eq_ast_type t' t = false).None ? + ] (refl_eq ? (eq_ast_type t' t)) + ]. + +definition preast_to_ast_var_checkb ≝ +λd.λe:aux_env_type d.λt:ast_type.λsig:(Σb'.ast_var d e b' t).λb:bool. + match sig with [ sigma_intro b' var ⇒ + match eq_bool b' b + return λx.eq_bool b' b = x → option (ast_var d e b t) + with + [ true ⇒ λp:(eq_bool b' b = true).Some ? (eq_rect ? b' (λb.ast_var d e b t) var b (eqbool_to_eq ?? p)) + | false ⇒ λp:(eq_bool b' b = false).None ? + ] (refl_eq ? (eq_bool b' b)) + ]. + +definition preast_to_ast_var_checkt ≝ +λd.λe:aux_env_type d.λb:bool.λsig:(Σt'.ast_var d e b t').λt:ast_type. + match sig with [ sigma_intro t' var ⇒ + match eq_ast_type t' t + return λx.eq_ast_type t' t = x → option (ast_var d e b t) + with + [ true ⇒ λp:(eq_ast_type t' t = true).Some ? (eq_rect ? t' (λt.ast_var d e b t) var t (eqasttype_to_eq ?? p)) + | false ⇒ λp:(eq_ast_type t' t = false).None ? + ] (refl_eq ? (eq_ast_type t' t)) + ]. + +definition preast_to_ast_var_check ≝ +λd.λe:aux_env_type d.λsig:(Σb'.(Σt'.ast_var d e b' t')).λb:bool.λt:ast_type. + opt_map ?? (preast_to_ast_var_checkt d e (sigmaFst ?? sig) (sigmaSnd ?? sig) t) + (λres1.opt_map ?? (preast_to_ast_var_checkb d e t ≪(sigmaFst ?? sig),res1≫ b) + (λres2.Some ? res2)). (* PREAST_EXPR_BYTE8 : byte8 → preast_expr @@ -51,6 +102,9 @@ qed. PREAST_EXPR_DIV: preast_expr → preast_expr → preast_expr PREAST_EXPR_SHR: preast_expr → preast_expr → preast_expr PREAST_EXPR_SHL: preast_expr → preast_expr → preast_expr + PREAST_EXPR_AND: preast_expr → preast_expr → preast_expr + PREAST_EXPR_OR: preast_expr → preast_expr → preast_expr + PREAST_EXPR_XOR: preast_expr → preast_expr → preast_expr PREAST_EXPR_GT : preast_expr → preast_expr → preast_expr PREAST_EXPR_GTE: preast_expr → preast_expr → preast_expr PREAST_EXPR_LT : preast_expr → preast_expr → preast_expr @@ -65,84 +119,494 @@ qed. PREAST_EXPR_W32toW16: preast_expr → preast_expr PREAST_EXPR_ID: preast_var → preast_expr *) -definition preast_to_ast_expr_check ≝ - λe:aux_env_type.λv:Σt'.ast_expr e t'.λt:ast_base_type. - match v with - [ sigma_intro t' expr ⇒ - match eq_ast_base_type t' t - return λb.eq_ast_base_type t' t = b → option (ast_expr e t) - with - [ true ⇒ λp.Some ? (eq_rect ? t' (λt.ast_expr e t) expr t (pippo ?? p)) - | false ⇒ λp.None ? - ] (refl_eq ? (eq_ast_base_type t' t)) - ]. - -let rec preast_to_ast_expr (preast:preast_expr) (e:aux_env_type) on preast : option (Σt:ast_base_type.ast_expr e t) ≝ +let rec preast_to_ast_expr (preast:preast_expr) (d:nat) (e:aux_env_type d) on preast : option (Σt.ast_expr d e t) ≝ match preast with - (* in pretty print diventa Some ? "≪AST_BASE_TYPE_BYTE8,AST_EXPR_BYTE8 e val≫" *) - [ PREAST_EXPR_BYTE8 val ⇒ Some ? ≪AST_BASE_TYPE_BYTE8, AST_EXPR_BYTE8 e val≫ - | PREAST_EXPR_WORD16 val ⇒ Some ? ≪AST_BASE_TYPE_WORD16, AST_EXPR_WORD16 e val≫ - | PREAST_EXPR_WORD32 val ⇒ Some ? ≪AST_BASE_TYPE_WORD32, AST_EXPR_WORD32 e val≫ + [ PREAST_EXPR_BYTE8 val ⇒ Some ? ≪?,(AST_EXPR_BYTE8 d e val)≫ + | PREAST_EXPR_WORD16 val ⇒ Some ? ≪?,(AST_EXPR_WORD16 d e val)≫ + | PREAST_EXPR_WORD32 val ⇒ Some ? ≪?,(AST_EXPR_WORD32 d e val)≫ + | PREAST_EXPR_NEG subExpr ⇒ - opt_map ?? (preast_to_ast_expr subExpr e) - (λsigmaRes:Σt:ast_base_type.ast_expr e t.Some ? ≪sigmaFst ?? sigmaRes, AST_EXPR_NEG e (sigmaFst ?? sigmaRes) (sigmaSnd ?? sigmaRes)≫) + opt_map ?? (preast_to_ast_expr subExpr d e) + (λsigmaRes:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes (AST_TYPE_BASE bType)) + (λres.Some ? ≪?,(AST_EXPR_NEG d e ? res)≫) + | _ ⇒ None ? ]) | PREAST_EXPR_NOT subExpr ⇒ - opt_map ?? (preast_to_ast_expr subExpr e) - (λsigmaRes:Σt:ast_base_type.ast_expr e t.Some ? ≪sigmaFst ?? sigmaRes, AST_EXPR_NOT e (sigmaFst ?? sigmaRes) (sigmaSnd ?? sigmaRes)≫) + opt_map ?? (preast_to_ast_expr subExpr d e) + (λsigmaRes:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes (AST_TYPE_BASE bType)) + (λres.Some ? ≪?,(AST_EXPR_NOT d e ? res)≫) + | _ ⇒ None ? ]) | PREAST_EXPR_COM subExpr ⇒ - opt_map ?? (preast_to_ast_expr subExpr e) - (λsigmaRes:Σt:ast_base_type.ast_expr e t.Some ? ≪sigmaFst ?? sigmaRes, AST_EXPR_COM e (sigmaFst ?? sigmaRes) (sigmaSnd ?? sigmaRes)≫) + opt_map ?? (preast_to_ast_expr subExpr d e) + (λsigmaRes:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes (AST_TYPE_BASE bType)) + (λres.Some ? ≪?,(AST_EXPR_COM d e ? res)≫) + | _ ⇒ None ? ]) + | PREAST_EXPR_ADD subExpr1 subExpr2 ⇒ - opt_map ?? (preast_to_ast_expr subExpr1 e) - (λsigmaRes1:Σt:ast_base_type.ast_expr e t.opt_map ?? (preast_to_ast_expr subExpr2 e) - (λsigmaRes2.opt_map ?? (preast_to_ast_expr_check e sigmaRes2 (sigmaFst ?? sigmaRes1)) - (λres2.Some ? (≪sigmaFst ?? sigmaRes1,AST_EXPR_ADD e (sigmaFst ?? sigmaRes1) (sigmaSnd ?? sigmaRes1) res2≫)))) - | _ ⇒ None ? - ] + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_ADD d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_SUB subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_SUB d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_MUL subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_MUL d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_DIV subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_DIV d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + + | PREAST_EXPR_SHR subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE AST_BASE_TYPE_BYTE8)) + (λres2.Some ? ≪?,(AST_EXPR_SHR d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_SHL subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE AST_BASE_TYPE_BYTE8)) + (λres2.Some ? ≪?,(AST_EXPR_SHL d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_AND subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_AND d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_OR subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_OR d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_XOR subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_XOR d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_GT subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_GT d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_GTE subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_GTE d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_LT subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_LT d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_LTE subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_LTE d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_EQ subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_EQ d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + | PREAST_EXPR_NEQ subExpr1 subExpr2 ⇒ + opt_map ?? (preast_to_ast_expr subExpr1 d e) + (λsigmaRes1:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr subExpr2 d e) + (λsigmaRes2:(Σt.ast_expr d e t). + match (sigmaFst ?? sigmaRes1) with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes1 (AST_TYPE_BASE bType)) + (λres1.opt_map ?? (preast_to_ast_expr_check d e sigmaRes2 (AST_TYPE_BASE bType)) + (λres2.Some ? ≪?,(AST_EXPR_NEQ d e ? res1 res2)≫)) + | _ ⇒ None ? ])) + + | PREAST_EXPR_B8toW16 subExpr ⇒ + opt_map ?? (preast_to_ast_expr subExpr d e) + (λsigmaRes:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr_check d e sigmaRes (AST_TYPE_BASE AST_BASE_TYPE_BYTE8)) + (λres.Some ? ≪?,(AST_EXPR_B8toW16 d e res)≫)) + | PREAST_EXPR_B8toW32 subExpr ⇒ + opt_map ?? (preast_to_ast_expr subExpr d e) + (λsigmaRes:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr_check d e sigmaRes (AST_TYPE_BASE AST_BASE_TYPE_BYTE8)) + (λres.Some ? ≪?,(AST_EXPR_B8toW32 d e res)≫)) + | PREAST_EXPR_W16toB8 subExpr ⇒ + opt_map ?? (preast_to_ast_expr subExpr d e) + (λsigmaRes:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr_check d e sigmaRes (AST_TYPE_BASE AST_BASE_TYPE_WORD16)) + (λres.Some ? ≪?,(AST_EXPR_W16toB8 d e res)≫)) + | PREAST_EXPR_W16toW32 subExpr ⇒ + opt_map ?? (preast_to_ast_expr subExpr d e) + (λsigmaRes:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr_check d e sigmaRes (AST_TYPE_BASE AST_BASE_TYPE_WORD16)) + (λres.Some ? ≪?,(AST_EXPR_W16toW32 d e res)≫)) + | PREAST_EXPR_W32toB8 subExpr ⇒ + opt_map ?? (preast_to_ast_expr subExpr d e) + (λsigmaRes:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr_check d e sigmaRes (AST_TYPE_BASE AST_BASE_TYPE_WORD32)) + (λres.Some ? ≪?,(AST_EXPR_W32toB8 d e res)≫)) + | PREAST_EXPR_W32toW16 subExpr ⇒ + opt_map ?? (preast_to_ast_expr subExpr d e) + (λsigmaRes:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr_check d e sigmaRes (AST_TYPE_BASE AST_BASE_TYPE_WORD32)) + (λres.Some ? ≪?,(AST_EXPR_W32toW16 d e res)≫)) + + | PREAST_EXPR_ID var ⇒ + opt_map ?? (preast_to_ast_var var d e) + (λsigmaRes:(Σb.(Σt.ast_var d e b t)). + match sigmaRes with [ sigma_intro b sigmaRes' ⇒ + match sigmaRes' with [ sigma_intro t _ ⇒ + opt_map ?? (preast_to_ast_var_check d e sigmaRes b t) + (λres.Some ? ≪?,(AST_EXPR_ID d e ?? res)≫)]]) + ] (* PREAST_VAR_ID: aux_str_type → preast_var PREAST_VAR_ARRAY: preast_var → preast_expr → preast_var - PREAST_VAR_STRUCT: preast_var → nat → preast_var. + PREAST_VAR_STRUCT: preast_var → nat → preast_var *) -and preast_to_ast_var (preast:preast_var) (e:aux_env_type) on preast : option (Σb:bool.Σt:ast_type.ast_var e b t) ≝ - None ?. +and preast_to_ast_var (preast:preast_var) (d:nat) (e:aux_env_type d) on preast : option (Σb.(Σt.ast_var d e b t)) ≝ + match preast with + [ PREAST_VAR_ID name ⇒ + match checkb_desc_env d e name + return λx.checkb_desc_env d e name = x → option (Σb.(Σt.ast_var d e b t)) + with + [ true ⇒ λp:(checkb_desc_env d e name = true). + let desc ≝ get_desc_env d e name in + let b ≝ get_const_desc desc in + let t ≝ get_type_desc desc in + Some ? ≪b,≪t,(AST_VAR_ID d e b t (AST_ID d e name (checkbdescenv_to_checkdescenv d e name p)))≫≫ + | false ⇒ λp:(checkb_desc_env d e name = false).None ? + ] (refl_eq ? (checkb_desc_env d e name)) + + | PREAST_VAR_ARRAY subVar expr ⇒ + opt_map ?? (preast_to_ast_var subVar d e) + (λsigmaResV:(Σb.(Σt.ast_var d e b t)). + match sigmaResV with [ sigma_intro b sigmaResV' ⇒ + match sigmaResV' with [ sigma_intro t _ ⇒ + match t with + [ AST_TYPE_ARRAY subType dim ⇒ + opt_map ?? (preast_to_ast_var_check d e sigmaResV b (AST_TYPE_ARRAY subType dim)) + (λresVar. + (* ASSERTO: + 1) se l'indice e' un'espressione riducibile ad un valore deve essere gia' + stato fatto dal parser, e qui controllo la condizione OUT_OF_BOUND + 2) se l'indice non e' un'espressione riducibile ad un valore il controllo + OUT_OF_BOUND sara' fatto a run time + *) + match (match expr with + [ PREAST_EXPR_BYTE8 val ⇒ (λx.leb (nat_of_byte8 val) dim) + | PREAST_EXPR_WORD16 val ⇒ (λx.leb (nat_of_word16 val) dim) + | PREAST_EXPR_WORD32 val ⇒ (λx.leb (nat_of_word32 val) dim) + | _ ⇒ (λx.true) ]) expr with + [ true ⇒ + opt_map ?? (preast_to_ast_expr expr d e) + (λsigmaResE:(Σt.ast_expr d e t). + match sigmaFst ?? sigmaResE with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaResE (AST_TYPE_BASE bType)) + (λresExpr.Some ? ≪b,≪subType,(AST_VAR_ARRAY d e b subType dim resVar (AST_BASE_EXPR d e bType resExpr))≫≫) + | _ ⇒ None ? ]) + | false ⇒ None ? ]) + | _ ⇒ None ? ]]]) + + | PREAST_VAR_STRUCT subVar field ⇒ + opt_map ?? (preast_to_ast_var subVar d e) + (λsigmaRes:(Σb.(Σt.ast_var d e b t)). + match sigmaRes with [ sigma_intro b sigmaRes' ⇒ + match sigmaRes' with [ sigma_intro t _ ⇒ + match t with + [ AST_TYPE_STRUCT nelSubType ⇒ + opt_map ?? (preast_to_ast_var_check d e sigmaRes b (AST_TYPE_STRUCT nelSubType)) + (λresVar. + match ltb field (len_neList ? nelSubType) + return λx.(ltb field (len_neList ? nelSubType) = x) → option (Σb.(Σt.ast_var d e b t)) + with + [ true ⇒ λp:(ltb field (len_neList ? nelSubType) = true). + Some ? ≪b,≪(abs_nth_neList ? nelSubType field),(AST_VAR_STRUCT d e b nelSubType field resVar p)≫≫ + | false ⇒ λp:(ltb field (len_neList ? nelSubType) = false).None ? + ] (refl_eq ? (ltb field (len_neList ? nelSubType))) + ) + | _ ⇒ None ? ]]]) + ]. (* PREAST_INIT_VAL_BYTE8: byte8 → preast_init_val PREAST_INIT_VAL_WORD16: word16 → preast_init_val PREAST_INIT_VAL_WORD32: word32 → preast_init_val PREAST_INIT_VAL_ARRAY: ne_list preast_init_val → preast_init_val - PREAST_INIT_VAL_STRUCT: ne_list preast_init_val → preast_init_val. + PREAST_INIT_VAL_STRUCT: ne_list preast_init_val → preast_init_val *) -let rec preast_to_ast_init_val (preast:preast_init_val) (e:aux_env_type) on preast : option (sigma ast_type (ast_init e)) ≝ - None ?. +definition preast_to_ast_init_val_aux_array : +Πt.Πn.Prod (aux_ast_init_type t) (aux_ast_init_type (AST_TYPE_ARRAY t n)) → (aux_ast_init_type (AST_TYPE_ARRAY t (S n))) ≝ +λt:ast_type.λn:nat.λx:Prod (aux_ast_init_type t) (aux_ast_init_type (AST_TYPE_ARRAY t n)).x. + +definition preast_to_ast_init_val_aux_struct : +Πt.Πnel.Prod (aux_ast_init_type t) (aux_ast_init_type (AST_TYPE_STRUCT nel)) → (aux_ast_init_type (AST_TYPE_STRUCT («£t»&nel))) ≝ +λt:ast_type.λnel:ne_list ast_type.λx:Prod (aux_ast_init_type t) (aux_ast_init_type (AST_TYPE_STRUCT nel)).x. + +let rec preast_to_ast_init_val_aux (preast:preast_init_val) on preast : option (Σt.aux_ast_init_type t) ≝ + match preast with + [ PREAST_INIT_VAL_BYTE8 val ⇒ + Some (Σt.aux_ast_init_type t) ≪(AST_TYPE_BASE AST_BASE_TYPE_BYTE8),val≫ + | PREAST_INIT_VAL_WORD16 val ⇒ + Some (Σt.aux_ast_init_type t) ≪(AST_TYPE_BASE AST_BASE_TYPE_WORD16),val≫ + | PREAST_INIT_VAL_WORD32 val ⇒ + Some (Σt.aux_ast_init_type t) ≪(AST_TYPE_BASE AST_BASE_TYPE_WORD32),val≫ + + | PREAST_INIT_VAL_ARRAY nelSubVal ⇒ + let rec aux (nel:ne_list preast_init_val) on nel : option (Σt.aux_ast_init_type t) ≝ + match nel with + [ ne_nil h ⇒ + opt_map ?? (preast_to_ast_init_val_aux h) + (λsigmaRes.match sigmaRes with [ sigma_intro t res ⇒ + Some (Σt.aux_ast_init_type t) ≪(AST_TYPE_ARRAY t 0),res≫ ]) + | ne_cons h tl ⇒ + opt_map ?? (preast_to_ast_init_val_aux h) + (λsigmaRes1:(Σt.aux_ast_init_type t).opt_map ?? (aux tl) + (λsigmaRes2:(Σt.aux_ast_init_type t). + match sigmaRes1 with [ sigma_intro t1 res1 ⇒ + match sigmaRes2 with [ sigma_intro t2 res2 ⇒ + match t2 with + [ AST_TYPE_ARRAY bType dim ⇒ + match eq_ast_type t1 bType + return λx.(eq_ast_type t1 bType = x) → option (Σt.aux_ast_init_type t) + with + [ true ⇒ λp:(eq_ast_type t1 bType = true). + match eq_ast_type t2 (AST_TYPE_ARRAY bType dim) + return λy.(eq_ast_type t2 (AST_TYPE_ARRAY bType dim) = y) → option (Σt.aux_ast_init_type t) + with + [ true ⇒ λp':(eq_ast_type t2 (AST_TYPE_ARRAY bType dim) = true). + Some (Σt.aux_ast_init_type t) ≪(AST_TYPE_ARRAY bType (S dim)), + (preast_to_ast_init_val_aux_array bType dim + (pair (aux_ast_init_type bType) (aux_ast_init_type (AST_TYPE_ARRAY bType dim)) + (eq_rect ? t1 (λw.aux_ast_init_type w) res1 bType (eqasttype_to_eq ?? p)) + (eq_rect ? t2 (λz.aux_ast_init_type z) res2 (AST_TYPE_ARRAY bType dim) (eqasttype_to_eq ?? p'))))≫ + | false ⇒ λp':(eq_ast_type t2 (AST_TYPE_ARRAY bType dim) = false).None ? + ] (refl_eq ? (eq_ast_type t2 (AST_TYPE_ARRAY bType dim))) + | false ⇒ λp:(eq_ast_type t1 bType = false).None ? + ] (refl_eq ? (eq_ast_type t1 bType)) + | _ ⇒ None ? + ]]])) + ] in aux nelSubVal + + | PREAST_INIT_VAL_STRUCT nelSubVal ⇒ + let rec aux (nel:ne_list preast_init_val) on nel : option (Σt.aux_ast_init_type t) ≝ + match nel with + [ ne_nil h ⇒ + opt_map ?? (preast_to_ast_init_val_aux h) + (λsigmaRes:(Σt.aux_ast_init_type t).match sigmaRes with [ sigma_intro t res ⇒ + Some (Σt.aux_ast_init_type t) ≪(AST_TYPE_STRUCT («£t»)),res≫ ]) + | ne_cons h tl ⇒ + opt_map ?? (preast_to_ast_init_val_aux h) + (λsigmaRes1:(Σt.aux_ast_init_type t).opt_map ?? (aux tl) + (λsigmaRes2:(Σt.aux_ast_init_type t). + match sigmaRes1 with [ sigma_intro t1 res1 ⇒ + match sigmaRes2 with [ sigma_intro t2 res2 ⇒ + match t2 with + [ AST_TYPE_STRUCT nelSubType ⇒ + match eq_ast_type t2 (AST_TYPE_STRUCT nelSubType) + return λx.(eq_ast_type t2 (AST_TYPE_STRUCT nelSubType) = x) → option (Σt.aux_ast_init_type t) + with + [ true ⇒ λp:(eq_ast_type t2 (AST_TYPE_STRUCT nelSubType) = true). + Some (Σt.aux_ast_init_type t) ≪(AST_TYPE_STRUCT («£t1»&nelSubType)), + (preast_to_ast_init_val_aux_struct ?? + (pair (aux_ast_init_type t1) (aux_ast_init_type (AST_TYPE_STRUCT nelSubType)) + res1 + (eq_rect ? t2 (λy.aux_ast_init_type y) res2 (AST_TYPE_STRUCT nelSubType) (eqasttype_to_eq ?? p))))≫ + | false ⇒ λp:(eq_ast_type t2 (AST_TYPE_STRUCT nelSubType) = false).None ? + ] (refl_eq ? (eq_ast_type t2 (AST_TYPE_STRUCT nelSubType))) + | _ ⇒ None ? ]]])) + ] in aux nelSubVal + ]. (* PREAST_INIT_VAR: preast_var → preast_init - PREAST_INIT_VAL: preast_init_val → preast_init. + PREAST_INIT_VAL: preast_init_val → preast_init *) -definition preast_to_ast_init : preast_init → Πe:aux_env_type.option (sigma ast_type (ast_init e)) ≝ -λpreast:preast_init.λe:aux_env_type.None ?. +definition preast_to_ast_init : preast_init → Πd.Πe:aux_env_type d.option (Σt.ast_init d e t) ≝ +λpreast:preast_init.λd.λe:aux_env_type d.match preast with + [ PREAST_INIT_VAR var ⇒ + opt_map ?? (preast_to_ast_var var d e) + (λsigmaRes:(Σb.(Σt.ast_var d e b t)). + Some ? ≪?,(AST_INIT_VAR d e ?? (sigmaSnd ?? (sigmaSnd ?? sigmaRes)))≫) + + | PREAST_INIT_VAL val ⇒ + opt_map ?? (preast_to_ast_init_val_aux val) + (λsigmaRes:(Σt.aux_ast_init_type t). + Some ? ≪?,(AST_INIT_VAL d e ? (sigmaSnd ?? sigmaRes))≫) + ]. (* PREAST_STM_ASG: preast_var → preast_expr → preast_stm PREAST_STM_WHILE: preast_expr → preast_decl → preast_stm PREAST_STM_IF: ne_list (Prod preast_expr preast_decl) → option preast_decl → preast_stm *) -let rec preast_to_ast_stm (preast:preast_stm) (e:aux_env_type) on preast : option (ast_stm e) ≝ - None ? +definition preast_to_ast_base_expr : preast_expr → Πd.Πe:aux_env_type d.option (ast_base_expr d e) ≝ +λpreast:preast_expr.λd.λe:aux_env_type d. + opt_map ?? (preast_to_ast_expr preast d e) + (λsigmaRes:(Σt.ast_expr d e t). + match sigmaFst ?? sigmaRes with + [ AST_TYPE_BASE bType ⇒ + opt_map ?? (preast_to_ast_expr_check d e sigmaRes (AST_TYPE_BASE bType)) + (λres.Some ? (AST_BASE_EXPR d e ? res)) + | _ ⇒ None ? ]). + +let rec preast_to_ast_stm (preast:preast_stm) (d:nat) (e:aux_env_type d) on preast : option (ast_stm d e) ≝ + match preast with + [ PREAST_STM_ASG var expr ⇒ + opt_map ?? (preast_to_ast_var var d e) + (λsigmaResV:(Σb.(Σt.ast_var d e b t)). + match sigmaResV with [ sigma_intro _ sigmaResV' ⇒ + match sigmaResV' with [ sigma_intro t _ ⇒ + opt_map ?? (preast_to_ast_var_check d e sigmaResV false t) + (λresVar.opt_map ?? (preast_to_ast_expr expr d e) + (λsigmaResE:(Σt.ast_expr d e t).opt_map ?? (preast_to_ast_expr_check d e sigmaResE t) + (λresExpr.Some ? (AST_STM_ASG d e t resVar resExpr) + )))]]) + + | PREAST_STM_WHILE expr decl ⇒ + opt_map ?? (preast_to_ast_base_expr expr d e) + (λresExpr.opt_map ?? (preast_to_ast_decl decl (S d) (enter_env d e)) + (λresDecl.Some ? (AST_STM_WHILE d e resExpr resDecl))) + + | PREAST_STM_IF nelExprDecl optDecl ⇒ + opt_map ?? (fold_right_neList ?? (λh,t.opt_map ?? (preast_to_ast_base_expr (fst ?? h) d e) + (λresExpr.opt_map ?? (preast_to_ast_decl (snd ?? h) (S d) (enter_env d e)) + (λresDecl.opt_map ?? t + (λt'.Some ? («£(pair ?? resExpr resDecl)»&t'))))) + (Some ? (ne_nil ? (pair ?? (AST_BASE_EXPR d e AST_BASE_TYPE_BYTE8 (AST_EXPR_BYTE8 d e 〈x0,x0〉)) (AST_NO_DECL (S d) (enter_env d e) (nil ?))))) + nelExprDecl) + (λres.match optDecl with + [ None ⇒ Some ? (AST_STM_IF d e (cut_last_neList ? res) (None ?)) + | Some decl ⇒ opt_map ?? (preast_to_ast_decl decl (S d) (enter_env d e)) + (λresDecl.Some ? (AST_STM_IF d e (cut_last_neList ? res) (Some ? resDecl))) + ]) + ] (* PREAST_NO_DECL: list preast_stm → preast_decl - PREAST_DECL: bool → aux_str_type → ast_type → option preast_expr → preast_decl → preast_decl. + PREAST_CONST_DECL: aux_str_type → ast_type → preast_init → preast_decl → preast_decl + PREAST_VAR_DECL: aux_str_type → ast_type → option preast_init → preast_decl → preast_decl *) -and preast_to_ast_decl (preast:preast_decl) (e:aux_env_type) on preast : option (ast_decl e) ≝ - None ?. +and preast_to_ast_decl (preast:preast_decl) (d:nat) (e:aux_env_type d) on preast : option (ast_decl d e) ≝ + match preast with + [ PREAST_NO_DECL lPreastStm ⇒ + opt_map ?? (fold_right_list ?? (λh,t.opt_map ?? (preast_to_ast_stm h d e) + (λh'.opt_map ?? t + (λt'.Some ? ([h']@t')))) (Some ? (nil ?)) lPreastStm) + (λres.Some ? (AST_NO_DECL d e res)) + + | PREAST_CONST_DECL decName decType initExpr subPreastDecl ⇒ + match checkb_not_already_def_env d e decName + return λx.(checkb_not_already_def_env d e decName = x) → option (ast_decl d e) + with + [ true ⇒ λp:(checkb_not_already_def_env d e decName = true). + opt_map ?? (preast_to_ast_decl subPreastDecl d (add_desc_env d e decName true decType)) + (λdecl.opt_map ?? (preast_to_ast_init initExpr d e) + (λsigmaRes:(Σt:ast_type.ast_init d e t).opt_map ?? (preast_to_ast_init_check d e sigmaRes decType) + (λresInit.Some ? (AST_CONST_DECL d e decName decType + (checkbnotalreadydefenv_to_checknotalreadydefenv d e decName p) resInit decl)))) + | false ⇒ λp:(checkb_not_already_def_env d e decName = false).None ? + ] (refl_eq ? (checkb_not_already_def_env d e decName)) + + | PREAST_VAR_DECL decName decType optInitExpr subPreastDecl ⇒ + match checkb_not_already_def_env d e decName + return λx.(checkb_not_already_def_env d e decName = x) → option (ast_decl d e) + with + [ true ⇒ λp:(checkb_not_already_def_env d e decName = true). + opt_map ?? (preast_to_ast_decl subPreastDecl d (add_desc_env d e decName false decType)) + (λdecl.match optInitExpr with + [ None ⇒ Some ? (AST_VAR_DECL d e decName decType + (checkbnotalreadydefenv_to_checknotalreadydefenv d e decName p) (None ?) decl) + | Some initExpr ⇒ + opt_map ?? (preast_to_ast_init initExpr d e) + (λsigmaRes:(Σt:ast_type.ast_init d e t).opt_map ?? (preast_to_ast_init_check d e sigmaRes decType) + (λresInit.Some ? (AST_VAR_DECL d e decName decType + (checkbnotalreadydefenv_to_checknotalreadydefenv d e decName p) (Some ? resInit) decl)))]) + | false ⇒ λp:(checkb_not_already_def_env d e decName = false).None ? + ] (refl_eq ? (checkb_not_already_def_env d e decName)) + ]. (* - PREAST_ROOT: preast_decl → preast_root. + PREAST_ROOT: preast_decl → preast_root *) definition preast_to_ast ≝ λpreast:preast_root.match preast with - [ PREAST_ROOT decl ⇒ opt_map ?? (preast_to_ast_decl decl empty_env) + [ PREAST_ROOT decl ⇒ opt_map ?? (preast_to_ast_decl decl O empty_env) (λres.Some ? (AST_ROOT res)) ].