Mercurial > hg > CbC > CbC_gcc
view gcc/ada/par-load.adb @ 145:1830386684a0
gcc-9.2.0
| author | anatofuz |
|---|---|
| date | Thu, 13 Feb 2020 11:34:05 +0900 |
| parents | 84e7813d76e9 |
| children |
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------------------------------------------------------------------------------ -- -- -- GNAT COMPILER COMPONENTS -- -- -- -- P A R . L O A D -- -- -- -- B o d y -- -- -- -- Copyright (C) 1992-2019, Free Software Foundation, Inc. -- -- -- -- GNAT is free software; you can redistribute it and/or modify it under -- -- terms of the GNU General Public License as published by the Free Soft- -- -- ware Foundation; either version 3, or (at your option) any later ver- -- -- sion. GNAT is distributed in the hope that it will be useful, but WITH- -- -- OUT 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 distributed with GNAT; see file COPYING3. If not, go to -- -- http://www.gnu.org/licenses for a complete copy of the license. -- -- -- -- GNAT was originally developed by the GNAT team at New York University. -- -- Extensive contributions were provided by Ada Core Technologies Inc. -- -- -- ------------------------------------------------------------------------------ -- The Par.Load procedure loads all units that are definitely required before -- it makes any sense at all to proceed with semantic analysis, including -- with'ed units, corresponding specs for bodies, parents of child specs, -- and parents of subunits. All these units are loaded and pointers installed -- in the tree as described in the spec of package Lib. with Fname.UF; use Fname.UF; with Lib.Load; use Lib.Load; with Namet.Sp; use Namet.Sp; with Uname; use Uname; with Osint; use Osint; with Sinput.L; use Sinput.L; with Stylesw; use Stylesw; with GNAT.Spelling_Checker; use GNAT.Spelling_Checker; separate (Par) procedure Load is File_Name : File_Name_Type; -- Name of file for current unit, derived from unit name Cur_Unum : constant Unit_Number_Type := Current_Source_Unit; -- Unit number of unit that we just finished parsing. Note that we need -- to capture this, because Source_Unit will change as we parse new -- source files in the multiple main source file case. Curunit : constant Node_Id := Cunit (Cur_Unum); -- Compilation unit node for current compilation unit Loc : Source_Ptr := Sloc (Curunit); -- Source location for compilation unit node Save_Style_Check : Boolean; Save_Style_Checks : Style_Check_Options; -- Save style check so it can be restored later With_Cunit : Node_Id; -- Compilation unit node for withed unit Context_Node : Node_Id; -- Next node in context items list With_Node : Node_Id; -- N_With_Clause node Spec_Name : Unit_Name_Type; -- Unit name of required spec Body_Name : Unit_Name_Type; -- Unit name of corresponding body Unum : Unit_Number_Type; -- Unit number of loaded unit Limited_With_Found : Boolean := False; -- We load the context items in two rounds: the first round handles normal -- withed units and the second round handles Ada 2005 limited-withed units. -- This is required to allow the low-level circuitry that detects circular -- dependencies of units the correct notification of errors (see comment -- bellow). This variable is used to indicate that the second round is -- required. function Same_File_Name_Except_For_Case (Expected_File_Name : File_Name_Type; Actual_File_Name : File_Name_Type) return Boolean; -- Given an actual file name and an expected file name (the latter being -- derived from the unit name), determine if they are the same except for -- possibly different casing of letters. ------------------------------------ -- Same_File_Name_Except_For_Case -- ------------------------------------ function Same_File_Name_Except_For_Case (Expected_File_Name : File_Name_Type; Actual_File_Name : File_Name_Type) return Boolean is begin Get_Name_String (Actual_File_Name); Canonical_Case_File_Name (Name_Buffer (1 .. Name_Len)); declare Lower_Case_Actual_File_Name : String (1 .. Name_Len); begin Lower_Case_Actual_File_Name := Name_Buffer (1 .. Name_Len); Get_Name_String (Expected_File_Name); Canonical_Case_File_Name (Name_Buffer (1 .. Name_Len)); return Lower_Case_Actual_File_Name = Name_Buffer (1 .. Name_Len); end; end Same_File_Name_Except_For_Case; -- Start of processing for Load begin -- Don't do any loads if we already had a fatal error if Fatal_Error (Cur_Unum) = Error_Detected then return; end if; Save_Style_Check_Options (Save_Style_Checks); Save_Style_Check := Opt.Style_Check; -- If main unit, set Main_Unit_Entity (this will get overwritten if -- the main unit has a separate spec, that happens later on in Load) if Cur_Unum = Main_Unit then Main_Unit_Entity := Cunit_Entity (Main_Unit); end if; -- If we have no unit name, things are seriously messed up by previous -- errors, and we should not try to continue compilation. if Unit_Name (Cur_Unum) = No_Unit_Name then raise Unrecoverable_Error; end if; -- Next step, make sure that the unit name matches the file name -- and issue a warning message if not. We only output this for the -- main unit, since for other units it is more serious and is -- caught in a separate test below. We also inhibit the message in -- multiple unit per file mode, because in this case the relation -- between file name and unit name is broken. File_Name := Get_File_Name (Unit_Name (Cur_Unum), Subunit => Nkind (Unit (Cunit (Cur_Unum))) = N_Subunit); if Cur_Unum = Main_Unit and then Multiple_Unit_Index = 0 and then File_Name /= Unit_File_Name (Cur_Unum) and then (File_Names_Case_Sensitive or not Same_File_Name_Except_For_Case (File_Name, Unit_File_Name (Cur_Unum))) then Error_Msg_File_1 := File_Name; Error_Msg ("??file name does not match unit name, should be{", Sloc (Curunit)); end if; -- For units other than the main unit, the expected unit name is set and -- must be the same as the actual unit name, or we are in big trouble, and -- abandon the compilation since there are situations where this really -- gets us into bad trouble (e.g. some subunit situations). if Cur_Unum /= Main_Unit and then Expected_Unit (Cur_Unum) /= Unit_Name (Cur_Unum) then Loc := Error_Location (Cur_Unum); Error_Msg_File_1 := Unit_File_Name (Cur_Unum); Get_Name_String (Error_Msg_File_1); -- Check for predefined file case if Name_Len > 1 and then Name_Buffer (2) = '-' and then (Name_Buffer (1) = 'a' or else Name_Buffer (1) = 's' or else Name_Buffer (1) = 'i' or else Name_Buffer (1) = 'g') then declare Expect_Name : constant Unit_Name_Type := Expected_Unit (Cur_Unum); Actual_Name : constant Unit_Name_Type := Unit_Name (Cur_Unum); begin Error_Msg_Unit_1 := Expect_Name; Error_Msg -- CODEFIX ("$$ is not a predefined library unit!", Loc); -- In the predefined file case, we know the user did not -- construct their own package, but we got the wrong one. -- This means that the name supplied by the user crunched -- to something we recognized, but then the file did not -- contain the unit expected. Most likely this is due to -- a misspelling, e.g. -- with Ada.Calender; -- This crunches to a-calend, which indeed contains the unit -- Ada.Calendar, and we can diagnose the misspelling. This -- is a simple heuristic, but it catches many common cases -- of misspelling of predefined unit names without needing -- a full list of them. -- Before actually issuing the message, we will check that the -- unit name is indeed a plausible misspelling of the one we got. if Is_Bad_Spelling_Of (Name_Id (Expect_Name), Name_Id (Actual_Name)) then Error_Msg_Unit_1 := Actual_Name; Error_Msg -- CODEFIX ("possible misspelling of $$!", Loc); end if; end; -- Non-predefined file name case. In this case we generate a message -- and then we quit, because we are in big trouble, and if we try -- to continue compilation, we get into some nasty situations -- (for example in some subunit cases). else Error_Msg ("file { does not contain expected unit!", Loc); Error_Msg_Unit_1 := Expected_Unit (Cur_Unum); Error_Msg ("\\expected unit $!", Loc); Error_Msg_Unit_1 := Unit_Name (Cur_Unum); Error_Msg ("\\found unit $!", Loc); end if; -- In both cases, remove the unit if it is the last unit (which it -- normally (always?) will be) so that it is out of the way later. Remove_Unit (Cur_Unum); end if; -- If current unit is a body, load its corresponding spec if Nkind (Unit (Curunit)) = N_Package_Body or else Nkind (Unit (Curunit)) = N_Subprogram_Body then Spec_Name := Get_Spec_Name (Unit_Name (Cur_Unum)); Unum := Load_Unit (Load_Name => Spec_Name, Required => False, Subunit => False, Error_Node => Curunit, Corr_Body => Cur_Unum, PMES => (Cur_Unum = Main_Unit)); -- If we successfully load the unit, then set the spec/body pointers. -- Once again note that if the loaded unit has a fatal error, Load will -- have set our Fatal_Error flag to propagate this condition. if Unum /= No_Unit then Set_Library_Unit (Curunit, Cunit (Unum)); Set_Library_Unit (Cunit (Unum), Curunit); -- If this is a separate spec for the main unit, then we reset -- Main_Unit_Entity to point to the entity for this separate spec -- and this is also where we generate the SCO's for this spec. if Cur_Unum = Main_Unit then Main_Unit_Entity := Cunit_Entity (Unum); if Generate_SCO then SCO_Record_Raw (Unum); end if; end if; -- If we don't find the spec, then if we have a subprogram body, we -- are still OK, we just have a case of a body acting as its own spec elsif Nkind (Unit (Curunit)) = N_Subprogram_Body then Set_Acts_As_Spec (Curunit, True); Set_Library_Unit (Curunit, Curunit); -- Otherwise we do have an error, repeat the load request for the spec -- with Required set True to generate an appropriate error message. else Unum := Load_Unit (Load_Name => Spec_Name, Required => True, Subunit => False, Error_Node => Curunit); return; end if; -- If current unit is a child unit spec, load its parent. If the child unit -- is loaded through a limited with, the parent must be as well. elsif Nkind (Unit (Curunit)) = N_Package_Declaration or else Nkind (Unit (Curunit)) = N_Subprogram_Declaration or else Nkind (Unit (Curunit)) in N_Generic_Declaration or else Nkind (Unit (Curunit)) in N_Generic_Instantiation or else Nkind (Unit (Curunit)) in N_Renaming_Declaration then -- Turn style checks off for parent unit if not GNAT_Mode then Reset_Style_Check_Options; end if; Spec_Name := Get_Parent_Spec_Name (Unit_Name (Cur_Unum)); if Spec_Name /= No_Unit_Name then Unum := Load_Unit (Load_Name => Spec_Name, Required => True, Subunit => False, Error_Node => Curunit); if Unum /= No_Unit then Set_Parent_Spec (Unit (Curunit), Cunit (Unum)); end if; end if; -- If current unit is a subunit, then load its parent body elsif Nkind (Unit (Curunit)) = N_Subunit then Body_Name := Get_Parent_Body_Name (Unit_Name (Cur_Unum)); Unum := Load_Unit (Load_Name => Body_Name, Required => True, Subunit => False, Error_Node => Name (Unit (Curunit))); if Unum /= No_Unit then Set_Library_Unit (Curunit, Cunit (Unum)); end if; end if; -- Now we load with'ed units, with style checks turned off if not GNAT_Mode then Reset_Style_Check_Options; end if; -- Load the context items in two rounds: the first round handles normal -- withed units and the second round handles Ada 2005 limited-withed units. -- This is required to allow the low-level circuitry that detects circular -- dependencies of units the correct notification of the following error: -- limited with D; -- with D; with C; -- package C is ... package D is ... for Round in 1 .. 2 loop Context_Node := First (Context_Items (Curunit)); while Present (Context_Node) loop -- During the first round we check if there is some limited-with -- context clause; otherwise the second round will be skipped if Nkind (Context_Node) = N_With_Clause and then Round = 1 and then Limited_Present (Context_Node) then Limited_With_Found := True; end if; if Nkind (Context_Node) = N_With_Clause and then ((Round = 1 and then not Limited_Present (Context_Node)) or else (Round = 2 and then Limited_Present (Context_Node))) then With_Node := Context_Node; Spec_Name := Get_Unit_Name (With_Node); Unum := Load_Unit (Load_Name => Spec_Name, Required => False, Subunit => False, Error_Node => With_Node, Renamings => True, With_Node => Context_Node); -- If we find the unit, then set spec pointer in the N_With_Clause -- to point to the compilation unit for the spec. Remember that -- the Load routine itself sets our Fatal_Error flag if the loaded -- unit gets a fatal error, so we don't need to worry about that. if Unum /= No_Unit then Set_Library_Unit (With_Node, Cunit (Unum)); -- If the spec isn't found, then try finding the corresponding -- body, since it is possible that we have a subprogram body -- that is acting as a spec (since no spec is present). else Body_Name := Get_Body_Name (Spec_Name); Unum := Load_Unit (Load_Name => Body_Name, Required => False, Subunit => False, Error_Node => With_Node, Renamings => True); -- If we got a subprogram body, then mark that we are using -- the body as a spec in the file table, and set the spec -- pointer in the N_With_Clause to point to the body entity. if Unum /= No_Unit and then Nkind (Unit (Cunit (Unum))) = N_Subprogram_Body then With_Cunit := Cunit (Unum); Set_Library_Unit (With_Node, With_Cunit); Set_Acts_As_Spec (With_Cunit, True); Set_Library_Unit (With_Cunit, With_Cunit); -- If we couldn't find the body, or if it wasn't a body spec -- then we are in trouble. We make one more call to Load to -- require the spec. We know it will fail of course, the -- purpose is to generate the required error message (we prefer -- that this message refer to the missing spec, not the body) else Unum := Load_Unit (Load_Name => Spec_Name, Required => True, Subunit => False, Error_Node => With_Node, Renamings => True); -- Here we create a dummy package unit for the missing unit Unum := Create_Dummy_Package_Unit (With_Node, Spec_Name); Set_Library_Unit (With_Node, Cunit (Unum)); end if; end if; end if; Next (Context_Node); end loop; exit when not Limited_With_Found; end loop; -- Restore style/validity check mode for main unit Set_Style_Check_Options (Save_Style_Checks); Opt.Style_Check := Save_Style_Check; end Load;