lustrec / src / inliner.ml @ 1eda3e78
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(********************************************************************) 

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(* *) 
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(* The LustreC compiler toolset / The LustreC Development Team *) 
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(* Copyright 2012   ONERA  CNRS  INPT *) 
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(* *) 
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(* LustreC is free software, distributed WITHOUT ANY WARRANTY *) 
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(* under the terms of the GNU Lesser General Public License *) 
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(* version 2.1. *) 
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(* *) 
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(********************************************************************) 
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open LustreSpec 
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open Corelang 
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let check_node_name id = (fun t > 
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match t.top_decl_desc with 
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 Node nd > nd.node_id = id 
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 _ > false) 
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let rename_expr rename expr = expr_replace_var rename expr 
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let rename_eq rename eq = 
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{ eq with 
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eq_lhs = List.map rename eq.eq_lhs; 
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eq_rhs = rename_expr rename eq.eq_rhs 
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} 
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(* 
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expr, locals', eqs = inline_call id args' reset locals nodes 
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We select the called node equations and variables. 
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renamed_inputs = args 
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renamed_eqs 
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the resulting expression is tuple_of_renamed_outputs 
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TODO: convert the specification/annotation/assert and inject them 
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TODO: deal with reset 
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*) 
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let inline_call orig_expr args reset locals node = 
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let loc = orig_expr.expr_loc in 
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let uid = orig_expr.expr_tag in 
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let rename v = 
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if v = tag_true  v = tag_false then v else 
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(Format.fprintf Format.str_formatter "%s_%i_%s" 
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node.node_id uid v; 
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Format.flush_str_formatter ()) 
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in 
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let eqs' = List.map (rename_eq rename) (get_node_eqs node) 
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in 
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let rename_var v = { v with var_id = rename v.var_id } in 
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let inputs' = List.map rename_var node.node_inputs in 
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let outputs' = List.map rename_var node.node_outputs in 
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let locals' = List.map rename_var node.node_locals in 
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(* checking we are at the appropriate (early) step: node_checks and 
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node_gencalls should be empty (not yet assigned) *) 
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assert (node.node_checks = []); 
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assert (node.node_gencalls = []); 
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(* Bug included: todo deal with reset *) 
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assert (reset = None); 
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let assign_inputs = mkeq loc (List.map (fun v > v.var_id) inputs', args) in 
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let expr = expr_of_expr_list 
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loc 
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(List.map (fun v > mkexpr loc (Expr_ident v.var_id)) outputs') 
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in 
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let asserts' = (* We rename variables in assert expressions *) 
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List.map 
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(fun a > 
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{a with assert_expr = 
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let expr = a.assert_expr in 
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rename_expr rename expr 
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}) 
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node.node_asserts 
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in 
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expr, 
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inputs'@outputs'@locals'@locals, 
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assign_inputs::eqs', 
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asserts' 
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(* 
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new_expr, new_locals, new_eqs = inline_expr expr locals nodes 
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Each occurence of a node in nodes in the expr should be replaced by fresh 
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variables and the code of called node instance added to new_eqs 
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*) 
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let rec inline_expr expr locals nodes = 
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let inline_tuple el = 
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List.fold_right (fun e (el_tail, locals, eqs, asserts) > 
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let e', locals', eqs', asserts' = inline_expr e locals nodes in 
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e'::el_tail, locals', eqs'@eqs, asserts@asserts' 
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) el ([], locals, [], []) 
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in 
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let inline_pair e1 e2 = 
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let el', l', eqs', asserts' = inline_tuple [e1;e2] in 
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match el' with 
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 [e1'; e2'] > e1', e2', l', eqs', asserts' 
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 _ > assert false 
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in 
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let inline_triple e1 e2 e3 = 
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let el', l', eqs', asserts' = inline_tuple [e1;e2;e3] in 
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match el' with 
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 [e1'; e2'; e3'] > e1', e2', e3', l', eqs', asserts' 
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 _ > assert false 
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in 
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match expr.expr_desc with 
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 Expr_appl (id, args, reset) > 
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let args', locals', eqs', asserts' = inline_expr args locals nodes in 
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if List.exists (check_node_name id) nodes then 
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(* The node should be inlined *) 
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(* let _ = Format.eprintf "Inlining call to %s@." id in *) 
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let node = try List.find (check_node_name id) nodes 
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with Not_found > (assert false) in 
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let node = node_of_top node in 
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let node = inline_node node nodes in 
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let expr, locals', eqs'', asserts'' = 
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inline_call expr args' reset locals' node in 
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expr, locals', eqs'@eqs'', asserts'@asserts'' 
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else 
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(* let _ = Format.eprintf "Not inlining call to %s@." id in *) 
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{ expr with expr_desc = Expr_appl(id, args', reset)}, 
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locals', 
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eqs', 
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asserts' 
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(* For other cases, we just keep the structure, but convert subexpressions *) 
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 Expr_const _ 
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 Expr_ident _ > expr, locals, [], [] 
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 Expr_tuple el > 
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let el', l', eqs', asserts' = inline_tuple el in 
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{ expr with expr_desc = Expr_tuple el' }, l', eqs', asserts' 
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 Expr_ite (g, t, e) > 
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let g', t', e', l', eqs', asserts' = inline_triple g t e in 
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{ expr with expr_desc = Expr_ite (g', t', e') }, l', eqs', asserts' 
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 Expr_arrow (e1, e2) > 
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let e1', e2', l', eqs', asserts' = inline_pair e1 e2 in 
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{ expr with expr_desc = Expr_arrow (e1', e2') } , l', eqs', asserts' 
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 Expr_fby (e1, e2) > 
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let e1', e2', l', eqs', asserts' = inline_pair e1 e2 in 
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{ expr with expr_desc = Expr_fby (e1', e2') }, l', eqs', asserts' 
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 Expr_array el > 
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let el', l', eqs', asserts' = inline_tuple el in 
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{ expr with expr_desc = Expr_array el' }, l', eqs', asserts' 
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 Expr_access (e, dim) > 
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let e', l', eqs', asserts' = inline_expr e locals nodes in 
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{ expr with expr_desc = Expr_access (e', dim) }, l', eqs', asserts' 
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 Expr_power (e, dim) > 
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let e', l', eqs', asserts' = inline_expr e locals nodes in 
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{ expr with expr_desc = Expr_power (e', dim) }, l', eqs', asserts' 
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 Expr_pre e > 
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let e', l', eqs', asserts' = inline_expr e locals nodes in 
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{ expr with expr_desc = Expr_pre e' }, l', eqs', asserts' 
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 Expr_when (e, id, label) > 
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let e', l', eqs', asserts' = inline_expr e locals nodes in 
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{ expr with expr_desc = Expr_when (e', id, label) }, l', eqs', asserts' 
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 Expr_merge (id, branches) > 
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let el, l', eqs', asserts' = inline_tuple (List.map snd branches) in 
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let branches' = List.map2 (fun (label, _) v > label, v) branches el in 
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{ expr with expr_desc = Expr_merge (id, branches') }, l', eqs', asserts' 
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and inline_node nd nodes = 
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let new_locals, eqs, asserts = 
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List.fold_left (fun (locals, eqs, asserts) eq > 
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let eq_rhs', locals', new_eqs', asserts' = 
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inline_expr eq.eq_rhs locals nodes 
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in 
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locals', { eq with eq_rhs = eq_rhs' }::new_eqs'@eqs, asserts'@asserts 
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) (nd.node_locals, [], nd.node_asserts) (get_node_eqs nd) 
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in 
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{ nd with 
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node_locals = new_locals; 
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node_stmts = List.map (fun eq > Eq eq) eqs; 
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node_asserts = asserts; 
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} 
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let inline_all_calls node nodes = 
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let nd = match node.top_decl_desc with Node nd > nd  _ > assert false in 
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{ node with top_decl_desc = Node (inline_node nd nodes) } 
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let witness filename main_name orig inlined type_env clock_env = 
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let loc = Location.dummy_loc in 
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let rename_local_node nodes prefix id = 
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if List.exists (check_node_name id) nodes then 
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prefix ^ id 
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else 
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id 
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in 
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let main_orig_node = match (List.find (check_node_name main_name) orig).top_decl_desc with 
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Node nd > nd  _ > assert false in 
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let orig_rename = rename_local_node orig "orig_" in 
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let inlined_rename = rename_local_node inlined "inlined_" in 
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let identity = (fun x > x) in 
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let is_node top = match top.top_decl_desc with Node _ > true  _ > false in 
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let orig = rename_prog orig_rename identity identity orig in 
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let inlined = rename_prog inlined_rename identity identity inlined in 
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let nodes_origs, others = List.partition is_node orig in 
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let nodes_inlined, _ = List.partition is_node inlined in 
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(* One ok_i boolean variable per output var *) 
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let nb_outputs = List.length main_orig_node.node_outputs in 
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let ok_i = List.map (fun id > 
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mkvar_decl 
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loc 
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("OK" ^ string_of_int id, 
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{ty_dec_desc=Tydec_bool; ty_dec_loc=loc}, 
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{ck_dec_desc=Ckdec_any; ck_dec_loc=loc}, 
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false) 
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) (Utils.enumerate nb_outputs) 
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in 
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(* OK = ok_1 and ok_2 and ... ok_n1 *) 
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let ok_ident = "OK" in 
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let ok_output = mkvar_decl 
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loc 
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(ok_ident, 
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{ty_dec_desc=Tydec_bool; ty_dec_loc=loc}, 
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{ck_dec_desc=Ckdec_any; ck_dec_loc=loc}, 
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false) 
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in 
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let main_ok_expr = 
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let mkv x = mkexpr loc (Expr_ident x) in 
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match ok_i with 
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 [] > assert false 
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 [x] > mkv x.var_id 
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 hd::tl > 
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List.fold_left (fun accu elem > 
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mkpredef_call loc "&&" [mkv elem.var_id; accu] 
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) (mkv hd.var_id) tl 
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in 
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(* Building main node *) 
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let ok_i_eq = 
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{ eq_loc = loc; 
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eq_lhs = List.map (fun v > v.var_id) ok_i; 
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eq_rhs = 
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let inputs = expr_of_expr_list loc (List.map (fun v > mkexpr loc (Expr_ident v.var_id)) main_orig_node.node_inputs) in 
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let call_orig = 
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mkexpr loc (Expr_appl ("orig_" ^ main_name, inputs, None)) in 
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let call_inlined = 
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mkexpr loc (Expr_appl ("inlined_" ^ main_name, inputs, None)) in 
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let args = mkexpr loc (Expr_tuple [call_orig; call_inlined]) in 
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mkexpr loc (Expr_appl ("=", args, None)) 
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} in 
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let ok_eq = 
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{ eq_loc = loc; 
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eq_lhs = [ok_ident]; 
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eq_rhs = main_ok_expr; 
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} in 
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let main_node = { 
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node_id = "check"; 
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node_type = Types.new_var (); 
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node_clock = Clocks.new_var true; 
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node_inputs = main_orig_node.node_inputs; 
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node_outputs = [ok_output]; 
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node_locals = ok_i; 
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node_gencalls = []; 
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node_checks = []; 
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node_asserts = []; 
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node_stmts = [Eq ok_i_eq; Eq ok_eq]; 
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node_dec_stateless = false; 
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node_stateless = None; 
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node_spec = Some 
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{requires = []; 
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ensures = [mkeexpr loc (mkexpr loc (Expr_ident ok_ident))]; 
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behaviors = []; 
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spec_loc = loc 
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}; 
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node_annot = []; 
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} 
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in 
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let main = [{ top_decl_desc = Node main_node; top_decl_loc = loc; top_decl_owner = filename; top_decl_itf = false }] in 
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let new_prog = others@nodes_origs@nodes_inlined@main in 
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let _ = Typing.type_prog type_env new_prog in 
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let _ = Clock_calculus.clock_prog clock_env new_prog in 
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let witness_file = (Options.get_witness_dir filename) ^ "/" ^ "inliner_witness.lus" in 
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let witness_out = open_out witness_file in 
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let witness_fmt = Format.formatter_of_out_channel witness_out in 
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Format.fprintf witness_fmt 
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"(* Generated lustre file to check validity of inlining process *)@."; 
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Printers.pp_prog witness_fmt new_prog; 
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Format.fprintf witness_fmt "@."; 
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() (* xx *) 
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let global_inline basename prog type_env clock_env = 
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(* We select the main node desc *) 
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let main_node, other_nodes, other_tops = 
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List.fold_left 
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(fun (main_opt, nodes, others) top > 
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match top.top_decl_desc with 
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 Node nd when nd.node_id = !Options.main_node > 
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Some top, nodes, others 
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 Node _ > main_opt, top::nodes, others 
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 _ > main_opt, nodes, top::others) 
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(None, [], []) prog 
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in 
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(* Recursively each call of a node in the top node is replaced *) 
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let main_node = Utils.desome main_node in 
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let main_node' = inline_all_calls main_node other_nodes in 
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let res = main_node'::other_tops in 
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if !Options.witnesses then ( 
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witness 
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basename 
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(match main_node.top_decl_desc with Node nd > nd.node_id  _ > assert false) 
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prog res type_env clock_env 
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); 
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res 
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(* Local Variables: *) 
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(* compilecommand:"make C .." *) 
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(* End: *) 