1------------------------------------------------------------------------------ 2-- -- 3-- GNAT COMPILER COMPONENTS -- 4-- -- 5-- S E M _ C H 1 2 -- 6-- -- 7-- S p e c -- 8-- -- 9-- Copyright (C) 1992-2015, Free Software Foundation, Inc. -- 10-- -- 11-- GNAT is free software; you can redistribute it and/or modify it under -- 12-- terms of the GNU General Public License as published by the Free Soft- -- 13-- ware Foundation; either version 3, or (at your option) any later ver- -- 14-- sion. GNAT is distributed in the hope that it will be useful, but WITH- -- 15-- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY -- 16-- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License -- 17-- for more details. You should have received a copy of the GNU General -- 18-- Public License distributed with GNAT; see file COPYING3. If not, go to -- 19-- http://www.gnu.org/licenses for a complete copy of the license. -- 20-- -- 21-- GNAT was originally developed by the GNAT team at New York University. -- 22-- Extensive contributions were provided by Ada Core Technologies Inc. -- 23-- -- 24------------------------------------------------------------------------------ 25 26with Inline; use Inline; 27with Types; use Types; 28 29package Sem_Ch12 is 30 procedure Analyze_Generic_Package_Declaration (N : Node_Id); 31 procedure Analyze_Generic_Subprogram_Declaration (N : Node_Id); 32 procedure Analyze_Package_Instantiation (N : Node_Id); 33 procedure Analyze_Procedure_Instantiation (N : Node_Id); 34 procedure Analyze_Function_Instantiation (N : Node_Id); 35 procedure Analyze_Formal_Object_Declaration (N : Node_Id); 36 procedure Analyze_Formal_Type_Declaration (N : Node_Id); 37 procedure Analyze_Formal_Subprogram_Declaration (N : Node_Id); 38 procedure Analyze_Formal_Package_Declaration (N : Node_Id); 39 40 function Build_Function_Wrapper 41 (Formal_Subp : Entity_Id; 42 Actual_Subp : Entity_Id) return Node_Id; 43 -- In GNATprove mode, create a wrapper function for actuals that are 44 -- functions with any number of formal parameters, in order to propagate 45 -- their contract to the renaming declarations generated for them. This 46 -- is called after the renaming declaration created for the formal in the 47 -- instance has been analyzed, and the actual is known. 48 49 function Build_Operator_Wrapper 50 (Formal_Subp : Entity_Id; 51 Actual_Subp : Entity_Id) return Node_Id; 52 -- In GNATprove mode, create a wrapper function for actuals that are 53 -- operators, in order to propagate their contract to the renaming 54 -- declarations generated for them. The types are (the instances of) 55 -- the types of the formal subprogram. 56 57 procedure Start_Generic; 58 -- Must be invoked before starting to process a generic spec or body 59 60 procedure End_Generic; 61 -- Must be invoked just at the end of the end of the processing of a 62 -- generic spec or body. 63 64 procedure Check_Generic_Child_Unit 65 (Gen_Id : Node_Id; 66 Parent_Installed : in out Boolean); 67 -- If the name of the generic unit in an instantiation or a renaming is a 68 -- selected component, then the prefix may be an instance and the selector 69 -- may designate a child unit. Retrieve the parent generic and search for 70 -- the child unit that must be declared within. Similarly, if this is the 71 -- name of a generic child unit within an instantiation of its own parent, 72 -- retrieve the parent generic. If the parent is installed as a result of 73 -- this call, then Parent_Installed is set True, otherwise Parent_Installed 74 -- is unchanged by the call. 75 76 function Copy_Generic_Node 77 (N : Node_Id; 78 Parent_Id : Node_Id; 79 Instantiating : Boolean) return Node_Id; 80 -- Copy the tree for a generic unit or its body. The unit is copied 81 -- repeatedly: once to produce a copy on which semantic analysis of 82 -- the generic is performed, and once for each instantiation. The tree 83 -- being copied is not semantically analyzed, except that references to 84 -- global entities are marked on terminal nodes. Note that this function 85 -- copies any aspect specifications from the input node N to the returned 86 -- node, as well as the setting of the Has_Aspects flag. 87 88 function Get_Instance_Of (A : Entity_Id) return Entity_Id; 89 -- Retrieve actual associated with given generic parameter. 90 -- If A is uninstantiated or not a generic parameter, return A. 91 92 function Get_Package_Instantiation_Node (A : Entity_Id) return Node_Id; 93 -- Given the entity of a unit that is an instantiation, retrieve the 94 -- original instance node. This is used when loading the instantiations 95 -- of the ancestors of a child generic that is being instantiated. 96 97 procedure Instantiate_Package_Body 98 (Body_Info : Pending_Body_Info; 99 Inlined_Body : Boolean := False; 100 Body_Optional : Boolean := False); 101 -- Called after semantic analysis, to complete the instantiation of 102 -- package instances. The flag Inlined_Body is set if the body is 103 -- being instantiated on the fly for inlined purposes. 104 -- 105 -- The flag Body_Optional indicates that the call is for an instance 106 -- that precedes the current instance in the same declarative part. 107 -- This call is needed when instantiating a nested generic whose body 108 -- is to be found in the body of an instance. Normally we instantiate 109 -- package bodies only when they appear in the main unit, or when their 110 -- contents are needed for a nested generic G. If unit U contains several 111 -- instances I1, I2, etc. and I2 contains a nested generic, then when U 112 -- appears in the context of some other unit P that contains an instance 113 -- of G, we compile the body of I2, but not that of I1. However, when we 114 -- compile U as the main unit, we compile both bodies. This will lead to 115 -- lead to link-time errors if the compilation of I1 generates public 116 -- symbols, because those in I2 will receive different names in both 117 -- cases. This forces us to analyze the body of I1 even when U is not the 118 -- main unit. We don't want this additional mechanism to generate an error 119 -- when the body of the generic for I1 is not present, and this is the 120 -- reason for the presence of the flag Body_Optional, which is exchanged 121 -- between the current procedure and Load_Parent_Of_Generic. 122 123 procedure Instantiate_Subprogram_Body 124 (Body_Info : Pending_Body_Info; 125 Body_Optional : Boolean := False); 126 -- Called after semantic analysis, to complete the instantiation of 127 -- function and procedure instances. The flag Body_Optional has the 128 -- same purpose as described for Instantiate_Package_Body. 129 130 function Need_Subprogram_Instance_Body 131 (N : Node_Id; 132 Subp : Entity_Id) return Boolean; 133 -- If a subprogram instance is inlined, indicate that the body of it 134 -- must be created, to be used in inlined calls by the back-end. The 135 -- subprogram may be inlined because the generic itself carries the 136 -- pragma, or because a pragma appears for the instance in the scope. 137 -- of the instance. 138 139 procedure Save_Global_References (N : Node_Id); 140 -- Traverse the original generic unit, and capture all references to 141 -- entities that are defined outside of the generic in the analyzed 142 -- tree for the template. These references are copied into the original 143 -- tree, so that they appear automatically in every instantiation. 144 -- A critical invariant in this approach is that if an id in the generic 145 -- resolves to a local entity, the corresponding id in the instance 146 -- will resolve to the homologous entity in the instance, even though 147 -- the enclosing context for resolution is different, as long as the 148 -- global references have been captured as described here. 149 150 -- Because instantiations can be nested, the environment of the instance, 151 -- involving the actuals and other data-structures, must be saved and 152 -- restored in stack-like fashion. Front-end inlining also uses these 153 -- structures for the management of private/full views. 154 155 procedure Save_Global_References_In_Aspects (N : Node_Id); 156 -- Save all global references in the aspect specifications of node N 157 158 procedure Set_Copied_Sloc_For_Inlined_Body (N : Node_Id; E : Entity_Id); 159 -- This procedure is used when a subprogram body is inlined. This process 160 -- shares the same circuitry as the creation of an instantiated copy of 161 -- a generic template. The call to this procedure establishes a new source 162 -- file entry representing the inlined body as an instantiation, marked as 163 -- an inlined body (so that errout can distinguish cases for generating 164 -- error messages, otherwise the treatment is identical). In this call 165 -- N is the subprogram body and E is the defining identifier of the 166 -- subprogram in question. The resulting Sloc adjustment factor is 167 -- saved as part of the internal state of the Sem_Ch12 package for use 168 -- in subsequent calls to copy nodes. 169 170 procedure Save_Env 171 (Gen_Unit : Entity_Id; 172 Act_Unit : Entity_Id); 173 -- Because instantiations can be nested, the compiler maintains a stack 174 -- of environments that holds variables relevant to the current instance: 175 -- most importanty Instantiated_Parent, Exchanged_Views, Hidden_Entities, 176 -- and others (see full list in Instance_Env). 177 178 procedure Restore_Env; 179 -- After processing an instantiation, or aborting one because of semantic 180 -- errors, remove the current Instantiation_Env from Instantation_Envs. 181 182 procedure Initialize; 183 -- Initializes internal data structures 184 185 procedure Check_Private_View (N : Node_Id); 186 -- Check whether the type of a generic entity has a different view between 187 -- the point of generic analysis and the point of instantiation. If the 188 -- view has changed, then at the point of instantiation we restore the 189 -- correct view to perform semantic analysis of the instance, and reset 190 -- the current view after instantiation. The processing is driven by the 191 -- current private status of the type of the node, and Has_Private_View, 192 -- a flag that is set at the point of generic compilation. If view and 193 -- flag are inconsistent then the type is updated appropriately. 194 -- 195 -- This subprogram is used in Check_Generic_Actuals and Copy_Generic_Node, 196 -- and is exported here for the purpose of front-end inlining (see Exp_Ch6. 197 -- Expand_Inlined_Call.Process_Formals). 198 199end Sem_Ch12; 200