-- Iir to ortho translator. -- Copyright (C) 2002 - 2014 Tristan Gingold -- -- 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 2 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 . with Vhdl.Errors; use Vhdl.Errors; with Files_Map; with Vhdl.Utils; use Vhdl.Utils; with Vhdl.Std_Package; use Vhdl.Std_Package; with Vhdl.Canon; with Translation; use Translation; with Trans.Chap2; with Trans.Chap3; with Trans.Chap5; with Trans.Chap6; with Trans.Chap7; with Trans.Chap8; with Trans.Chap9; with Trans.Chap14; with Trans.Rtis; with Trans.Helpers2; use Trans.Helpers2; with Trans_Decls; use Trans_Decls; with Trans.Foreach_Non_Composite; package body Trans.Chap4 is use Trans.Helpers; -- Get the ortho type for an object of mode MODE. function Get_Object_Type (Tinfo : Type_Info_Acc; Kind : Object_Kind_Type) return O_Tnode is begin case Tinfo.Type_Mode is when Type_Mode_Complex_Record | Type_Mode_Complex_Array | Type_Mode_Protected => -- For a complex type, use a pointer. return Tinfo.Ortho_Ptr_Type (Kind); when others => return Tinfo.Ortho_Type (Kind); end case; end Get_Object_Type; -- Return the pointer type for Tinfo. -- For a fat array, this is the fat pointer to slightly optimize accesses. function Get_Object_Ptr_Type (Tinfo : Type_Info_Acc; Kind : Object_Kind_Type) return O_Tnode is begin if Tinfo.Type_Mode in Type_Mode_Unbounded then -- Fat pointers are already pointers, no need to create an -- additional indirection. return Tinfo.Ortho_Type (Kind); else if Kind = Mode_Signal and then Tinfo.Type_Mode in Type_Mode_Scalar then -- A scalar signal is already a pointer. return Tinfo.Ortho_Type (Kind); else return Tinfo.Ortho_Ptr_Type (Kind); end if; end if; end Get_Object_Ptr_Type; function Lop2M (Obj_Ptr : O_Lnode; Tinfo : Type_Info_Acc; Mode : Object_Kind_Type) return Mnode is begin if (Mode = Mode_Signal and then Tinfo.Type_Mode in Type_Mode_Scalar) or else Tinfo.Type_Mode in Type_Mode_Unbounded then return Lv2M (Obj_Ptr, Tinfo, Mode); else return Lp2M (Obj_Ptr, Tinfo, Mode); end if; end Lop2M; procedure Assign_Obj_Ptr (Dest : Mnode; Src : Mnode) is Mode : constant Object_Kind_Type := Get_Object_Kind (Dest); Tinfo : constant Type_Info_Acc := Get_Type_Info (Dest); begin pragma Assert (Mode = Get_Object_Kind (Src)); pragma Assert (Tinfo.Type_Mode = Get_Type_Info (Src).Type_Mode); if Tinfo.Type_Mode in Type_Mode_Unbounded then Copy_Fat_Pointer (Stabilize (Dest), Stabilize (Src)); else if Mode = Mode_Signal and then Tinfo.Type_Mode in Type_Mode_Scalar then New_Assign_Stmt (M2Lv (Dest), M2E (Src)); else New_Assign_Stmt (M2Lp (Dest), M2Addr (Src)); end if; end if; end Assign_Obj_Ptr; procedure Create_Object (El : Iir) is Obj_Type : O_Tnode; Info : Object_Info_Acc; Tinfo : Type_Info_Acc; Def : Iir; Val : constant Iir := Get_Default_Value (El); Storage : O_Storage; Deferred : Iir; begin -- Be sure the object type was translated. if Get_Kind (El) = Iir_Kind_Constant_Declaration and then Get_Deferred_Declaration_Flag (El) = False and then Get_Deferred_Declaration (El) /= Null_Iir then -- This is a full constant declaration which completes a previous -- incomplete constant declaration. -- -- Do not create the subtype of this full constant declaration, -- since it was already created by the deferred declaration. -- Use the type of the deferred declaration. Deferred := Get_Deferred_Declaration (El); Def := Get_Type (Deferred); Info := Get_Info (Deferred); Set_Info (El, Info); else Chap3.Translate_Object_Subtype_Indication (El); Info := Add_Info (El, Kind_Object); Def := Get_Type (El); end if; Tinfo := Get_Info (Def); Obj_Type := Get_Object_Type (Tinfo, Mode_Value); case Get_Kind (El) is when Iir_Kind_Variable_Declaration | Iir_Kind_Interface_Constant_Declaration => Info.Object_Var := Create_Var (Create_Var_Identifier (El), Obj_Type); when Iir_Kind_Constant_Declaration => if Get_Deferred_Declaration (El) /= Null_Iir then -- This is a full constant declaration (in a body) of a -- deferred constant declaration (in a package). Storage := O_Storage_Public; else Storage := Global_Storage; end if; if Info.Object_Var = Null_Var then -- Not a full constant declaration (ie a value for an -- already declared constant). -- Must create the declaration. if Chap7.Is_Static_Constant (El) then Info.Object_Static := True; Info.Object_Var := Create_Global_Const (Create_Identifier (El), Obj_Type, Global_Storage, O_Cnode_Null); else Info.Object_Static := False; Info.Object_Var := Create_Var (Create_Var_Identifier (El), Obj_Type, Global_Storage); end if; end if; if Get_Deferred_Declaration (El) = Null_Iir and then Info.Object_Static and then Storage /= O_Storage_External then -- Deferred constant are never considered as locally static. -- FIXME: to be improved ? -- open_temp/close_temp only required for transient types. Open_Temp; Define_Global_Const (Info.Object_Var, Chap7.Translate_Static_Expression (Val, Def)); Close_Temp; end if; when others => Error_Kind ("create_objet", El); end case; end Create_Object; procedure Create_Signal (Decl : Iir) is Sig_Type_Def : constant Iir := Get_Type (Decl); Type_Info : Type_Info_Acc; Info : Signal_Info_Acc; begin if Get_Kind (Decl) /= Iir_Kind_Anonymous_Signal_Declaration then Chap3.Translate_Object_Subtype_Indication (Decl); end if; Type_Info := Get_Info (Sig_Type_Def); Info := Add_Info (Decl, Kind_Signal); Info.Signal_Sig := Create_Var (Create_Var_Identifier (Decl, "_SIG", 0), Get_Object_Type (Type_Info, Mode_Signal)); if Get_Kind (Decl) = Iir_Kind_Interface_Signal_Declaration then -- For interfaces, create a pointer so that there is no need to -- update a copy if the association is collapsed. Info.Signal_Valp := Create_Var (Create_Var_Identifier (Decl, "_VALP", 0), Get_Object_Ptr_Type (Type_Info, Mode_Value)); if Get_Default_Value (Decl) /= Null_Iir then -- Default value for ports. Info.Signal_Val := Create_Var (Create_Var_Identifier (Decl, "_INIT", 0), Get_Object_Type (Type_Info, Mode_Value)); end if; else Info.Signal_Val := Create_Var (Create_Var_Identifier (Decl, "_VAL", 0), Get_Object_Type (Type_Info, Mode_Value)); end if; case Get_Kind (Decl) is when Iir_Kind_Signal_Declaration | Iir_Kind_Interface_Signal_Declaration => Rtis.Generate_Signal_Rti (Decl); when Iir_Kind_Guard_Signal_Declaration | Iir_Kind_Anonymous_Signal_Declaration => -- No name created for guard signal. null; when others => Error_Kind ("create_signal", Decl); end case; end Create_Signal; procedure Create_Implicit_Signal (Decl : Iir) is Sig_Type_Def : constant Iir := Get_Type (Decl); Type_Info : constant Type_Info_Acc := Get_Info (Sig_Type_Def); Info : Signal_Info_Acc; begin -- The type of DECL is already known: either bit, or boolean or the -- type of the prefix. Info := Add_Info (Decl, Kind_Signal); Info.Signal_Sig := Create_Var (Create_Uniq_Identifier, Get_Object_Type (Type_Info, Mode_Signal)); Info.Signal_Val := Create_Var (Create_Uniq_Identifier, Get_Object_Type (Type_Info, Mode_Value)); end Create_Implicit_Signal; procedure Create_File_Object (El : Iir_File_Declaration) is Obj_Type_Def : constant Iir := Get_Type (El); Obj_Type : constant O_Tnode := Get_Ortho_Type (Obj_Type_Def, Mode_Value); Info : Ortho_Info_Acc; begin Info := Add_Info (El, Kind_Object); Info.Object_Var := Create_Var (Create_Var_Identifier (El), Obj_Type); end Create_File_Object; procedure Create_Package_Interface (Inter : Iir) is Pkg : constant Iir := Get_Uninstantiated_Package_Decl (Inter); Pkg_Info : constant Ortho_Info_Acc := Get_Info (Pkg); Info : Ortho_Info_Acc; begin Info := Add_Info (Inter, Kind_Package_Instance); -- The spec Info.Package_Instance_Spec_Var := Create_Var (Create_Var_Identifier (Inter, "SPEC", 0), Pkg_Info.Package_Spec_Ptr_Type); Set_Scope_Via_Var_Ptr (Info.Package_Instance_Spec_Scope, Info.Package_Instance_Spec_Var); -- The body Info.Package_Instance_Body_Var := Create_Var (Create_Var_Identifier (Inter, "BODY", 0), Pkg_Info.Package_Body_Ptr_Type); Set_Scope_Via_Var_Ptr (Info.Package_Instance_Body_Scope, Info.Package_Instance_Body_Var); Chap2.Instantiate_Info_Package (Inter); end Create_Package_Interface; procedure Allocate_Complex_Object (Obj_Type : Iir; Alloc_Kind : Allocation_Kind; Var : in out Mnode) is Type_Info : constant Type_Info_Acc := Get_Type_Info (Var); Kind : constant Object_Kind_Type := Get_Object_Kind (Var); begin -- Cannot allocate unconstrained object (since size is unknown). pragma Assert (Type_Info.Type_Mode not in Type_Mode_Unbounded); if not Is_Complex_Type (Type_Info) then -- Object is not complex. return; end if; -- Allocate variable. New_Assign_Stmt (M2Lp (Var), Gen_Alloc (Alloc_Kind, Chap3.Get_Subtype_Size (Obj_Type, Mnode_Null, Kind), Type_Info.Ortho_Ptr_Type (Kind))); end Allocate_Complex_Object; -- Note : OBJ can be a tree. -- FIXME: should use translate_aggregate_others. procedure Init_Array_Object (Obj : Mnode; Obj_Type : Iir) is -- Type of the object. Type_Info : constant Type_Info_Acc := Get_Info (Obj_Type); Sobj : Mnode; -- Iterator for the elements. Index : O_Dnode; Upper_Limit : O_Enode; Upper_Var : O_Dnode; Label : O_Snode; begin -- Iterate on all elements of the object. Open_Temp; if Type_Info.Type_Mode = Type_Mode_Unbounded_Array then Sobj := Stabilize (Obj); else Sobj := Obj; end if; Upper_Limit := Chap3.Get_Array_Length (Sobj, Obj_Type); if Type_Info.Type_Mode = Type_Mode_Static_Array then Upper_Var := O_Dnode_Null; else -- Hoist the computation of the limit before the loop. Upper_Var := Create_Temp_Init (Ghdl_Index_Type, Upper_Limit); end if; Index := Create_Temp (Ghdl_Index_Type); Init_Var (Index); Start_Loop_Stmt (Label); if Upper_Var /= O_Dnode_Null then Upper_Limit := New_Obj_Value (Upper_Var); end if; Gen_Exit_When (Label, New_Compare_Op (ON_Eq, New_Obj_Value (Index), Upper_Limit, Ghdl_Bool_Type)); Init_Object (Chap6.Translate_Indexed_Name_By_Offset (Sobj, Obj_Type, Index), Get_Element_Subtype (Obj_Type)); Inc_Var (Index); Finish_Loop_Stmt (Label); Close_Temp; end Init_Array_Object; procedure Init_Protected_Object (Obj : Mnode; Obj_Type : Iir) is Info : constant Type_Info_Acc := Get_Info (Obj_Type); Assoc : O_Assoc_List; begin -- Call the initializer. Start_Association (Assoc, Info.B.Prot_Init_Subprg); Subprgs.Add_Subprg_Instance_Assoc (Assoc, Info.B.Prot_Init_Instance); -- Use of M2Lp is a little bit fragile (not sure we get the -- variable, but should work: we didn't stabilize it). New_Assign_Stmt (M2Lp (Obj), New_Function_Call (Assoc)); end Init_Protected_Object; procedure Fini_Protected_Object (Decl : Iir) is Info : constant Type_Info_Acc := Get_Info (Get_Type (Decl)); Obj : Mnode; Assoc : O_Assoc_List; begin Obj := Chap6.Translate_Name (Decl, Mode_Value); -- Call the Finalizator. Start_Association (Assoc, Info.B.Prot_Final_Subprg); New_Association (Assoc, M2E (Obj)); New_Procedure_Call (Assoc); end Fini_Protected_Object; function Get_Scalar_Initial_Value (Atype : Iir) return O_Enode is Tinfo : constant Type_Info_Acc := Get_Info (Atype); begin case Tinfo.Type_Mode is when Type_Mode_Scalar => return Chap14.Translate_Left_Type_Attribute (Atype); when Type_Mode_Acc | Type_Mode_Bounds_Acc => return New_Lit (New_Null_Access (Tinfo.Ortho_Type (Mode_Value))); when others => Error_Kind ("get_scalar_initial_value", Atype); end case; end Get_Scalar_Initial_Value; procedure Init_Object (Obj : Mnode; Obj_Type : Iir) is Tinfo : constant Type_Info_Acc := Get_Type_Info (Obj); begin case Tinfo.Type_Mode is when Type_Mode_Scalar | Type_Mode_Acc | Type_Mode_Bounds_Acc => New_Assign_Stmt (M2Lv (Obj), Get_Scalar_Initial_Value (Obj_Type)); when Type_Mode_Arrays => Init_Array_Object (Obj, Obj_Type); when Type_Mode_Records => declare List : constant Iir_Flist := Get_Elements_Declaration_List (Obj_Type); Sobj : Mnode; El : Iir_Element_Declaration; begin Open_Temp; Sobj := Stabilize (Obj); for I in Flist_First .. Flist_Last (List) loop El := Get_Nth_Element (List, I); Init_Object (Chap6.Translate_Selected_Element (Sobj, El), Get_Type (El)); end loop; Close_Temp; end; when Type_Mode_Protected => Init_Protected_Object (Obj, Obj_Type); when Type_Mode_Unknown | Type_Mode_File => raise Internal_Error; end case; end Init_Object; -- Return True iff subtype indication of DECL is a subtype attribute. function Is_Object_Subtype_Attribute (Decl : Iir) return Boolean is Ind : constant Iir := Get_Subtype_Indication (Decl); begin return Ind /= Null_Iir and then Get_Kind (Ind) = Iir_Kind_Subtype_Attribute; end Is_Object_Subtype_Attribute; procedure Elab_Subtype_Attribute (Decl : Iir; Name_Val : Mnode; Name_Sig : Mnode) is Ind : constant Iir := Get_Subtype_Indication (Decl); Name : Mnode; Bnd : Mnode; begin Name := Chap6.Translate_Name (Get_Prefix (Ind), Mode_Value); Bnd := Chap3.Get_Composite_Bounds (Name); if Name_Sig /= Mnode_Null then Stabilize (Bnd); New_Assign_Stmt (M2Lp (Chap3.Get_Composite_Bounds (Name_Sig)), M2Addr (Bnd)); end if; New_Assign_Stmt (M2Lp (Chap3.Get_Composite_Bounds (Name_Val)), M2Addr (Bnd)); end Elab_Subtype_Attribute; procedure Elab_Maybe_Subtype_Attribute (Decl : Iir; Name_Val : Mnode; Name_Sig : Mnode) is begin case Get_Kind (Decl) is when Iir_Kind_Anonymous_Signal_Declaration => return; when others => if not Is_Object_Subtype_Attribute (Decl) then return; end if; end case; Elab_Subtype_Attribute (Decl, Name_Val, Name_Sig); end Elab_Maybe_Subtype_Attribute; -- If SIZE is larger than the threshold, call __ghdl_check_stack_allocation -- to raise an error if the size is too large. There are two threshold: -- one set at compile time (Check_Stack_Allocation_Threshold) and one set -- at run-time. -- -- Right now, this function is called only for allocation of a complex -- object on the stack (constant or variable). But there are more sources -- of stack allocation (temporary aggregate, unbounded objects, individual -- assocs...) function Maybe_Check_Stack_Allocation (Size : O_Enode) return O_Enode is Val : O_Dnode; If_Blk : O_If_Block; Assoc : O_Assoc_List; begin if Flag_Check_Stack_Allocation = 0 then return Size; end if; Val := Create_Temp_Init (Ghdl_Index_Type, Size); Start_If_Stmt (If_Blk, New_Compare_Op (ON_Ge, New_Obj_Value (Val), New_Lit (Check_Stack_Allocation_Threshold), Ghdl_Bool_Type)); Start_Association (Assoc, Ghdl_Check_Stack_Allocation); New_Association (Assoc, New_Obj_Value (Val)); New_Procedure_Call (Assoc); Finish_If_Stmt (If_Blk); return New_Obj_Value (Val); end Maybe_Check_Stack_Allocation; procedure Elab_Object_Storage (Obj : Iir) is Obj_Type : constant Iir := Get_Type (Obj); Obj_Info : constant Object_Info_Acc := Get_Info (Obj); Name_Node : Mnode; Type_Info : Type_Info_Acc; Alloc_Kind : Allocation_Kind; Size : O_Enode; begin -- Elaborate subtype. case Get_Kind (Obj) is when Iir_Kind_Attribute_Value => null; when others => if Is_Object_Subtype_Attribute (Obj) then Type_Info := Get_Info (Obj_Type); if Type_Info.Type_Mode in Type_Mode_Unbounded then -- Copy bounds and allocate base. Name_Node := Get_Var (Obj_Info.Object_Var, Type_Info, Mode_Value); Stabilize (Name_Node); Elab_Maybe_Subtype_Attribute (Obj, Name_Node, Mnode_Null); Alloc_Kind := Get_Alloc_Kind_For_Var (Obj_Info.Object_Var); Chap3.Allocate_Unbounded_Composite_Base (Alloc_Kind, Name_Node, Get_Base_Type (Obj_Type)); return; end if; else Chap3.Elab_Object_Subtype_Indication (Obj); end if; end case; -- Now the subtype is elaborated, its info is defined. Type_Info := Get_Info (Obj_Type); -- FIXME: the object type may be a fat array! -- FIXME: fat array + aggregate ? if Type_Info.Type_Mode = Type_Mode_Protected then -- Protected object will be created by its INIT function. null; elsif Is_Unbounded_Type (Type_Info) then -- Allocated during initialization. null; elsif Is_Complex_Type (Type_Info) then -- FIXME: avoid allocation if the value is a string and -- the object is a constant Name_Node := Get_Var (Obj_Info.Object_Var, Type_Info, Mode_Value); Alloc_Kind := Get_Alloc_Kind_For_Var (Obj_Info.Object_Var); Size := Chap3.Get_Subtype_Size (Obj_Type, Mnode_Null, Mode_Value); if Alloc_Kind = Alloc_Stack then Size := Maybe_Check_Stack_Allocation (Size); end if; -- Was: Allocate_Complex_Object. New_Assign_Stmt (M2Lp (Name_Node), Gen_Alloc (Alloc_Kind, Size, Type_Info.Ortho_Ptr_Type (Mode_Value))); end if; end Elab_Object_Storage; -- Generate code to create object OBJ and initialize it with value VAL. procedure Elab_Object_Init (Name : Mnode; Obj : Iir; Value : Iir; Alloc_Kind : Allocation_Kind) is Obj_Type : constant Iir := Get_Type (Obj); Type_Info : constant Type_Info_Acc := Get_Info (Obj_Type); Name_Node : Mnode; Value_Node : O_Enode; begin -- Note: no temporary variable region is created, as the allocation -- may be performed on the stack. if Value = Null_Iir then -- Performs default initialization. Open_Temp; Init_Object (Name, Obj_Type); Close_Temp; elsif Get_Kind (Value) = Iir_Kind_Aggregate then if Type_Info.Type_Mode in Type_Mode_Unbounded and then not Is_Object_Subtype_Attribute (Obj) then -- Allocate. declare Aggr_Type : constant Iir := Get_Type (Value); Aggr_Base_Type : constant Iir := Get_Base_Type (Aggr_Type); begin Name_Node := Stabilize (Name); if Get_Constraint_State (Aggr_Type) /= Fully_Constrained then -- Allocate bounds Chap3.Allocate_Unbounded_Composite_Bounds (Alloc_Kind, Name_Node, Aggr_Base_Type); -- Translate bounds Chap7.Translate_Aggregate_Bounds (Stabilize (Chap3.Get_Composite_Bounds (Name_Node)), Value); -- Allocate base Chap3.Allocate_Unbounded_Composite_Base (Alloc_Kind, Name_Node, Aggr_Base_Type); else Chap3.Create_Composite_Subtype (Aggr_Type); if Alloc_Kind = Alloc_Stack then -- Short-cut: don't allocate bounds. New_Assign_Stmt (M2Lp (Chap3.Get_Composite_Bounds (Name_Node)), M2Addr (Chap3.Get_Composite_Type_Bounds (Aggr_Type))); Chap3.Allocate_Unbounded_Composite_Base (Alloc_Kind, Name_Node, Aggr_Base_Type); else Chap3.Translate_Object_Allocation (Name_Node, Alloc_Kind, Aggr_Base_Type, Chap3.Get_Composite_Type_Bounds (Aggr_Type)); end if; end if; end; else Name_Node := Name; end if; Chap7.Translate_Aggregate (Name_Node, Obj_Type, Value); else Value_Node := Chap7.Translate_Expression (Value, Obj_Type); if Type_Info.Type_Mode in Type_Mode_Unbounded then declare S : Mnode; begin Name_Node := Stabilize (Name); S := Stabilize (E2M (Value_Node, Type_Info, Mode_Value)); if Get_Kind (Value) = Iir_Kind_String_Literal8 and then Get_Kind (Obj) = Iir_Kind_Constant_Declaration then -- No need to allocate space for the object. Copy_Fat_Pointer (Name_Node, S); else Chap3.Translate_Object_Allocation (Name_Node, Alloc_Kind, Obj_Type, Chap3.Get_Composite_Bounds (S)); Chap3.Translate_Object_Copy (Name_Node, S, Obj_Type); end if; end; else Chap7.Translate_Assign (Name, Value_Node, Value, Obj_Type, Obj); end if; end if; end Elab_Object_Init; -- Generate code to create object OBJ and initialize it with value VAL. procedure Elab_Object_Value (Obj : Iir; Value : Iir) is Obj_Info : constant Object_Info_Acc := Get_Info (Obj); Alloc_Kind : constant Allocation_Kind := Get_Alloc_Kind_For_Var (Obj_Info.Object_Var); Name : constant Mnode := Get_Var (Obj_Info.Object_Var, Get_Info (Get_Type (Obj)), Mode_Value); begin Elab_Object_Storage (Obj); Elab_Object_Init (Name, Obj, Value, Alloc_Kind); if Alloc_Kind = Alloc_Return then -- If the object is allocated on the return stack, avoid -- deallocation. Deallocation must be done manually (this concerns -- procedures with suspension). Disable_Stack2_Release; end if; end Elab_Object_Value; -- Create code to elaborate OBJ. procedure Elab_Object (Obj : Iir) is Value : constant Iir := Get_Default_Value (Obj); Obj1 : Iir; begin -- Set default value. if Get_Kind (Obj) = Iir_Kind_Constant_Declaration then if Get_Deferred_Declaration_Flag (Obj) then -- No code generation for a deferred constant. return; end if; if Get_Kind (Value) = Iir_Kind_Overflow_Literal then -- An overflow can be static, but must still generate an error -- at run time. Chap6.Gen_Bound_Error (Obj); return; end if; if Get_Info (Obj).Object_Static then -- A static object is pre-initialized. return; end if; Obj1 := Get_Deferred_Declaration (Obj); if Obj1 = Null_Iir then Obj1 := Obj; end if; else Obj1 := Obj; end if; New_Debug_Line_Stmt (Get_Line_Number (Obj)); -- Still use the default value of the not deferred constant. -- FIXME: what about composite types. Elab_Object_Value (Obj1, Value); end Elab_Object; procedure Fini_Object (Obj : Iir) is Obj_Type : constant Iir := Get_Type (Obj); Type_Info : constant Type_Info_Acc := Get_Info (Obj_Type); begin case Type_Mode_Valid (Type_Info.Type_Mode) is when Type_Mode_Unbounded => declare V : Mnode; begin Open_Temp; V := Chap6.Translate_Name (Obj, Mode_Value); Stabilize (V); Chap3.Gen_Deallocate (New_Value (M2Lp (Chap3.Get_Composite_Bounds (V)))); Chap3.Gen_Deallocate (New_Value (M2Lp (Chap3.Get_Composite_Base (V)))); Close_Temp; end; when Type_Mode_Complex_Array | Type_Mode_Complex_Record | Type_Mode_Protected => Chap3.Gen_Deallocate (New_Value (M2Lp (Chap6.Translate_Name (Obj, Mode_Value)))); when Type_Mode_Scalar | Type_Mode_Static_Record | Type_Mode_Static_Array | Type_Mode_Acc | Type_Mode_Bounds_Acc => null; when Type_Mode_File => -- FIXME: free file ? null; end case; end Fini_Object; function Get_Nbr_Signals (Sig : Mnode; Sig_Type : Iir) return O_Enode is Info : constant Type_Info_Acc := Get_Info (Sig_Type); begin case Info.Type_Mode is when Type_Mode_Scalar => -- Note: here we discard SIG... return New_Lit (Ghdl_Index_1); when Type_Mode_Arrays => declare Len : O_Dnode; If_Blk : O_If_Block; Ssig : Mnode; begin Ssig := Stabilize (Sig); Len := Create_Temp_Init (Ghdl_Index_Type, Chap3.Get_Array_Length (Ssig, Sig_Type)); -- Can dereference the first index only if the array is not a -- null array. Start_If_Stmt (If_Blk, New_Compare_Op (ON_Neq, New_Obj_Value (Len), New_Lit (Ghdl_Index_0), Ghdl_Bool_Type)); New_Assign_Stmt (New_Obj (Len), New_Dyadic_Op (ON_Mul_Ov, New_Obj_Value (Len), Get_Nbr_Signals (Chap3.Index_Base (Chap3.Get_Composite_Base (Ssig), Sig_Type, New_Lit (Ghdl_Index_0)), Get_Element_Subtype (Sig_Type)))); Finish_If_Stmt (If_Blk); return New_Obj_Value (Len); end; when Type_Mode_Records => declare List : constant Iir_Flist := Get_Elements_Declaration_List (Get_Base_Type (Sig_Type)); El : Iir; Res : O_Enode; E : O_Enode; Sig_El : Mnode; Ssig : Mnode; begin Ssig := Stabilize (Sig); Res := O_Enode_Null; for I in Flist_First .. Flist_Last (List) loop El := Get_Nth_Element (List, I); Sig_El := Chap6.Translate_Selected_Element (Ssig, El); E := Get_Nbr_Signals (Sig_El, Get_Type (El)); if Res /= O_Enode_Null then Res := New_Dyadic_Op (ON_Add_Ov, Res, E); else Res := E; end if; end loop; if Res = O_Enode_Null then -- Empty records. Res := New_Lit (Ghdl_Index_0); end if; return Res; end; when Type_Mode_Unknown | Type_Mode_File | Type_Mode_Acc | Type_Mode_Bounds_Acc | Type_Mode_Protected => raise Internal_Error; end case; end Get_Nbr_Signals; -- Get the leftest signal of SIG. -- The leftest signal of -- a scalar signal is itself, -- an array signal is the leftest, -- a record signal is the first element. function Get_Leftest_Signal (Sig: Mnode; Sig_Type : Iir) return Mnode is Res : Mnode; Res_Type : Iir; Info : Type_Info_Acc; begin Res := Sig; Res_Type := Sig_Type; loop Info := Get_Type_Info (Res); case Info.Type_Mode is when Type_Mode_Scalar => return Res; when Type_Mode_Arrays => Res := Chap3.Index_Base (Chap3.Get_Composite_Base (Res), Res_Type, New_Lit (Ghdl_Index_0)); Res_Type := Get_Element_Subtype (Res_Type); when Type_Mode_Records => declare El_List : constant Iir_Flist := Get_Elements_Declaration_List (Get_Base_Type (Res_Type)); Element : constant Iir := Get_Nth_Element (El_List, 0); begin Res := Chap6.Translate_Selected_Element (Res, Element); Res_Type := Get_Type (Element); end; when Type_Mode_Unknown | Type_Mode_File | Type_Mode_Acc | Type_Mode_Bounds_Acc | Type_Mode_Protected => raise Internal_Error; end case; end loop; end Get_Leftest_Signal; -- Add func and instance. procedure Add_Associations_For_Resolver (Assoc : in out O_Assoc_List; Func_Decl : Iir) is Func_Info : constant Subprg_Info_Acc := Get_Info (Func_Decl); Resolv_Info : constant Subprg_Resolv_Info_Acc := Func_Info.Subprg_Resolv; Val : O_Enode; begin New_Association (Assoc, New_Lit (New_Subprogram_Address (Resolv_Info.Resolv_Func, Ghdl_Ptr_Type))); if Subprgs.Has_Subprg_Instance (Resolv_Info.Var_Instance) then Val := New_Convert_Ov (Subprgs.Get_Subprg_Instance (Resolv_Info.Var_Instance), Ghdl_Ptr_Type); else Val := New_Lit (New_Null_Access (Ghdl_Ptr_Type)); end if; New_Association (Assoc, Val); end Add_Associations_For_Resolver; type O_If_Block_Acc is access O_If_Block; type Elab_Signal_Data is record Value : Mnode; -- Default value of the signal. Init_Val : Mnode; -- If statement for a block of signals. If_Stmt : O_If_Block_Acc; -- True if the default value is set. Has_Val : Boolean; -- True if a resolution function was already attached. Already_Resolved : Boolean; -- True if the signal may already have been created. Check_Null : Boolean; end record; procedure Elab_Signal_Non_Composite (Targ : Mnode; Targ_Type : Iir; Data : Elab_Signal_Data) is Type_Info : constant Type_Info_Acc := Get_Info (Targ_Type); Create_Subprg : O_Dnode; Res : O_Enode; Assoc : O_Assoc_List; Init_Val : O_Enode; -- For the resolution function (if any). Func : Iir; If_Stmt : O_If_Block; Targ_Ptr : O_Dnode; Value : Mnode; begin if Data.Check_Null then Targ_Ptr := Create_Temp_Init (Ghdl_Signal_Ptr_Ptr, New_Unchecked_Address (M2Lv (Targ), Ghdl_Signal_Ptr_Ptr)); Start_If_Stmt (If_Stmt, New_Compare_Op (ON_Eq, New_Value (New_Acc_Value (New_Obj (Targ_Ptr))), New_Lit (New_Null_Access (Ghdl_Signal_Ptr)), Ghdl_Bool_Type)); end if; -- Set the value. Value := Stabilize (Data.Value); if Data.Has_Val then Init_Val := M2E (Data.Init_Val); else Init_Val := Get_Scalar_Initial_Value (Targ_Type); end if; New_Assign_Stmt (M2Lv (Value), Init_Val); -- Create the signal. case Type_Mode_Scalar (Type_Info.Type_Mode) is when Type_Mode_Scalar (Type_Mode_B1) => Create_Subprg := Ghdl_Create_Signal_B1; when Type_Mode_E8 => Create_Subprg := Ghdl_Create_Signal_E8; when Type_Mode_E32 => Create_Subprg := Ghdl_Create_Signal_E32; when Type_Mode_I32 | Type_Mode_P32 => Create_Subprg := Ghdl_Create_Signal_I32; when Type_Mode_P64 | Type_Mode_I64 => Create_Subprg := Ghdl_Create_Signal_I64; when Type_Mode_F64 => Create_Subprg := Ghdl_Create_Signal_F64; end case; Start_Association (Assoc, Create_Subprg); New_Association (Assoc, New_Unchecked_Address (M2Lv (Value), Ghdl_Ptr_Type)); if Get_Kind (Targ_Type) in Iir_Kinds_Subtype_Definition then Func := Has_Resolution_Function (Targ_Type); else Func := Null_Iir; end if; if Func /= Null_Iir and then not Data.Already_Resolved then Add_Associations_For_Resolver (Assoc, Func); else New_Association (Assoc, New_Lit (New_Null_Access (Ghdl_Ptr_Type))); New_Association (Assoc, New_Lit (New_Null_Access (Ghdl_Ptr_Type))); end if; Res := New_Function_Call (Assoc); if Data.Check_Null then New_Assign_Stmt (New_Acc_Value (New_Obj (Targ_Ptr)), Res); Finish_If_Stmt (If_Stmt); else New_Assign_Stmt (M2Lv (Targ), New_Convert_Ov (Res, Type_Info.Ortho_Type (Mode_Signal))); end if; end Elab_Signal_Non_Composite; function Elab_Signal_Prepare_Composite (Targ : Mnode; Targ_Type : Iir; Data : Elab_Signal_Data) return Elab_Signal_Data is Assoc : O_Assoc_List; Func : Iir; Res : Elab_Signal_Data; begin Res := Data; if Get_Kind (Targ_Type) in Iir_Kinds_Subtype_Definition then Func := Has_Resolution_Function (Targ_Type); if Func /= Null_Iir and then not Data.Already_Resolved then if Data.Check_Null then Res.If_Stmt := new O_If_Block; Start_If_Stmt (Res.If_Stmt.all, New_Compare_Op (ON_Eq, New_Convert_Ov (M2E (Get_Leftest_Signal (Targ, Targ_Type)), Ghdl_Signal_Ptr), New_Lit (New_Null_Access (Ghdl_Signal_Ptr)), Ghdl_Bool_Type)); --Res.Check_Null := False; end if; -- Add resolver. Start_Association (Assoc, Ghdl_Signal_Create_Resolution); Add_Associations_For_Resolver (Assoc, Func); New_Association (Assoc, New_Convert_Ov (M2Addr (Targ), Ghdl_Ptr_Type)); New_Association (Assoc, Get_Nbr_Signals (Targ, Targ_Type)); New_Procedure_Call (Assoc); Res.Already_Resolved := True; end if; end if; case Get_Info (Targ_Type).Type_Mode is when Type_Mode_Records => Res.Value := Stabilize (Data.Value); if Data.Has_Val then Res.Init_Val := Stabilize (Data.Init_Val); end if; when Type_Mode_Arrays => Res.Value := Chap3.Get_Composite_Base (Data.Value); if Data.Has_Val then Res.Init_Val := Chap3.Get_Composite_Base (Data.Init_Val); end if; when others => raise Internal_Error; end case; return Res; end Elab_Signal_Prepare_Composite; procedure Elab_Signal_Finish_Composite (Data : in out Elab_Signal_Data) is procedure Free is new Ada.Unchecked_Deallocation (Object => O_If_Block, Name => O_If_Block_Acc); begin if Data.If_Stmt /= null then Finish_If_Stmt (Data.If_Stmt.all); Free (Data.If_Stmt); end if; end Elab_Signal_Finish_Composite; function Elab_Signal_Update_Array (Data : Elab_Signal_Data; Targ_Type : Iir; Index : O_Dnode) return Elab_Signal_Data is N_Init_Val : Mnode; begin if Data.Has_Val then N_Init_Val := Chap3.Index_Base (Data.Init_Val, Targ_Type, New_Obj_Value (Index)); else N_Init_Val := Mnode_Null; end if; return Elab_Signal_Data' (Value => Chap3.Index_Base (Data.Value, Targ_Type, New_Obj_Value (Index)), Init_Val => N_Init_Val, Has_Val => Data.Has_Val, If_Stmt => null, Already_Resolved => Data.Already_Resolved, Check_Null => Data.Check_Null); end Elab_Signal_Update_Array; function Elab_Signal_Update_Record (Data : Elab_Signal_Data; Targ_Type : Iir; El : Iir_Element_Declaration) return Elab_Signal_Data is pragma Unreferenced (Targ_Type); N_Init_Val : Mnode; begin if Data.Has_Val then N_Init_Val := Chap6.Translate_Selected_Element (Data.Init_Val, El); else N_Init_Val := Mnode_Null; end if; return Elab_Signal_Data' (Value => Chap6.Translate_Selected_Element (Data.Value, El), Init_Val => N_Init_Val, Has_Val => Data.Has_Val, If_Stmt => null, Already_Resolved => Data.Already_Resolved, Check_Null => Data.Check_Null); end Elab_Signal_Update_Record; procedure Elab_Signal is new Foreach_Non_Composite (Data_Type => Elab_Signal_Data, Composite_Data_Type => Elab_Signal_Data, Do_Non_Composite => Elab_Signal_Non_Composite, Prepare_Data_Array => Elab_Signal_Prepare_Composite, Update_Data_Array => Elab_Signal_Update_Array, Finish_Data_Array => Elab_Signal_Finish_Composite, Prepare_Data_Record => Elab_Signal_Prepare_Composite, Update_Data_Record => Elab_Signal_Update_Record, Finish_Data_Record => Elab_Signal_Finish_Composite); -- Elaborate signal subtypes and allocate the storage for the object. procedure Elab_Signal_Declaration_Storage (Decl : Iir; Has_Copy : Boolean) is Is_Port : constant Boolean := Get_Kind (Decl) = Iir_Kind_Interface_Signal_Declaration; Sig_Type : constant Iir := Get_Type (Decl); Type_Info : Type_Info_Acc; Name_Sig : Mnode; Name_Val : Mnode; begin New_Debug_Line_Stmt (Get_Line_Number (Decl)); Open_Temp; if Get_Kind (Decl) /= Iir_Kind_Anonymous_Signal_Declaration then Chap3.Elab_Object_Subtype_Indication (Decl); end if; Type_Info := Get_Info (Sig_Type); if Type_Info.Type_Mode in Type_Mode_Unbounded then -- Allocate storage. if Has_Copy then Name_Sig := Chap6.Translate_Name (Decl, Mode_Signal); Name_Val := Mnode_Null; else Chap6.Translate_Signal_Name (Decl, Name_Sig, Name_Val); end if; Name_Sig := Stabilize (Name_Sig); if Name_Val /= Mnode_Null then Name_Val := Stabilize (Name_Val); Elab_Maybe_Subtype_Attribute (Decl, Name_Val, Name_Sig); Chap3.Allocate_Unbounded_Composite_Base (Alloc_System, Name_Val, Sig_Type); else Elab_Maybe_Subtype_Attribute (Decl, Name_Sig, Mnode_Null); end if; Chap3.Allocate_Unbounded_Composite_Base (Alloc_System, Name_Sig, Sig_Type); if Is_Port and then Get_Default_Value (Decl) /= Null_Iir then Name_Val := Chap6.Get_Port_Init_Value (Decl); Name_Val := Stabilize (Name_Val); Chap3.Allocate_Unbounded_Composite_Base (Alloc_System, Name_Val, Sig_Type); end if; elsif Is_Complex_Type (Type_Info) then if Has_Copy then Name_Sig := Chap6.Translate_Name (Decl, Mode_Signal); Name_Val := Mnode_Null; else Chap6.Translate_Signal_Name (Decl, Name_Sig, Name_Val); end if; Allocate_Complex_Object (Sig_Type, Alloc_System, Name_Sig); if Name_Val /= Mnode_Null then Allocate_Complex_Object (Sig_Type, Alloc_System, Name_Val); end if; if Is_Port and then Get_Default_Value (Decl) /= Null_Iir then Name_Val := Chap6.Get_Port_Init_Value (Decl); Allocate_Complex_Object (Sig_Type, Alloc_System, Name_Val); end if; elsif Is_Port then if not Has_Copy then -- A port that isn't collapsed. Allocate value. Name_Val := Chap6.Translate_Name (Decl, Mode_Value); New_Assign_Stmt (M2Lp (Name_Val), Gen_Alloc (Alloc_System, Chap3.Get_Object_Size (Name_Val, Sig_Type), Type_Info.Ortho_Ptr_Type (Mode_Value))); end if; end if; Close_Temp; end Elab_Signal_Declaration_Storage; function Has_Direct_Driver (Sig : Iir) return Boolean is Info : constant Ortho_Info_Acc := Get_Info (Get_Object_Prefix (Sig)); begin -- Can be an alias ? return Info.Kind = Kind_Signal and then Info.Signal_Driver /= Null_Var; end Has_Direct_Driver; procedure Elab_Direct_Driver_Declaration_Storage (Decl : Iir) is Sig_Type : constant Iir := Get_Type (Decl); Sig_Info : constant Ortho_Info_Acc := Get_Info (Decl); Type_Info : constant Type_Info_Acc := Get_Info (Sig_Type); Name_Node : Mnode; begin Open_Temp; if Type_Info.Type_Mode in Type_Mode_Unbounded then Name_Node := Get_Var (Sig_Info.Signal_Driver, Type_Info, Mode_Value); Name_Node := Stabilize (Name_Node); -- Copy bounds from signal. New_Assign_Stmt (M2Lp (Chap3.Get_Composite_Bounds (Name_Node)), M2Addr (Chap3.Get_Composite_Bounds (Chap6.Translate_Name (Decl, Mode_Signal)))); -- Allocate base. Chap3.Allocate_Unbounded_Composite_Base (Alloc_System, Name_Node, Sig_Type); elsif Is_Complex_Type (Type_Info) then Name_Node := Get_Var (Sig_Info.Signal_Driver, Type_Info, Mode_Value); Allocate_Complex_Object (Sig_Type, Alloc_System, Name_Node); end if; Close_Temp; end Elab_Direct_Driver_Declaration_Storage; -- Create signal object. -- Note: SIG can be a signal sub-element (used when signals are -- collapsed). -- If CHECK_NULL is TRUE, create the signal only if it was not yet -- created. procedure Elab_Signal_Declaration_Object (Sig : Iir; Parent : Iir; Check_Null : Boolean) is Decl : constant Iir := Strip_Denoting_Name (Sig); Sig_Type : constant Iir := Get_Type (Sig); Base_Decl : constant Iir := Get_Object_Prefix (Sig); Name_Sig : Mnode; Name_Val : Mnode; Value : Iir; Data : Elab_Signal_Data; begin New_Debug_Line_Stmt (Get_Line_Number (Sig)); Open_Temp; -- Set the name of the signal. declare Assoc : O_Assoc_List; begin Start_Association (Assoc, Ghdl_Signal_Name_Rti); New_Association (Assoc, New_Unchecked_Address (New_Obj (Get_Info (Base_Decl).Signal_Rti), Rtis.Ghdl_Rti_Access)); Rtis.Associate_Rti_Context (Assoc, Parent); New_Procedure_Call (Assoc); end; Chap6.Translate_Signal_Name (Decl, Name_Sig, Name_Val); -- Consistency check: a signal name is a signal. pragma Assert (Get_Object_Kind (Name_Sig) = Mode_Signal); Data.Value := Name_Val; if Decl = Base_Decl then Data.Already_Resolved := False; Data.Check_Null := Check_Null; Value := Get_Default_Value (Base_Decl); if Value = Null_Iir then Data.Has_Val := False; else Data.Has_Val := True; Data.Init_Val := Chap7.Translate_Expression (Value, Sig_Type); end if; else -- Sub signal. -- Do not add resolver. -- Do not use default value. Data.Already_Resolved := True; Data.Has_Val := False; Data.Check_Null := False; Value := Null_Iir; end if; Elab_Signal (Name_Sig, Sig_Type, Data); Close_Temp; if Value /= Null_Iir then Chap9.Destroy_Types (Value); end if; end Elab_Signal_Declaration_Object; procedure Elab_Signal_Declaration (Decl : Iir; Parent : Iir; Check_Null : Boolean) is begin Elab_Signal_Declaration_Storage (Decl, False); Elab_Signal_Declaration_Object (Decl, Parent, Check_Null); end Elab_Signal_Declaration; procedure Elab_Signal_Attribute (Decl : Iir) is Info : constant Signal_Info_Acc := Get_Info (Decl); Dtype : constant Iir := Get_Type (Decl); Type_Info : constant Type_Info_Acc := Get_Info (Dtype); Assoc : O_Assoc_List; Prefix : Iir; Prefix_Node : Mnode; Res : O_Enode; Val : O_Enode; Param : Iir; Subprg : O_Dnode; begin New_Debug_Line_Stmt (Get_Line_Number (Decl)); -- Create the signal (with the time) case Get_Kind (Decl) is when Iir_Kind_Stable_Attribute => Subprg := Ghdl_Create_Stable_Signal; when Iir_Kind_Quiet_Attribute => Subprg := Ghdl_Create_Quiet_Signal; when Iir_Kind_Transaction_Attribute => Subprg := Ghdl_Create_Transaction_Signal; when others => Error_Kind ("elab_signal_attribute", Decl); end case; Start_Association (Assoc, Subprg); New_Association (Assoc, New_Unchecked_Address (Get_Var (Info.Signal_Val), Ghdl_Ptr_Type)); case Get_Kind (Decl) is when Iir_Kind_Stable_Attribute | Iir_Kind_Quiet_Attribute => Param := Get_Parameter (Decl); if Param = Null_Iir then Val := New_Lit (New_Signed_Literal (Std_Time_Otype, 0)); else Val := Chap7.Translate_Expression (Param); end if; New_Association (Assoc, Val); when others => null; end case; Res := New_Convert_Ov (New_Function_Call (Assoc), Type_Info.Ortho_Type (Mode_Signal)); New_Assign_Stmt (Get_Var (Info.Signal_Sig), Res); -- Register all signals this depends on. Prefix := Get_Prefix (Decl); Prefix_Node := Chap6.Translate_Name (Prefix, Mode_Signal); Register_Signal (Prefix_Node, Get_Type (Prefix), Ghdl_Signal_Attribute_Register_Prefix); end Elab_Signal_Attribute; type Delayed_Signal_Data is record -- Value part of the signal. The signal itself is passed by a -- parameter. Targ_Val : Mnode; -- Prefix signal. Pfx : Mnode; -- Delay time. Param : Iir; end record; procedure Create_Delayed_Signal_Noncomposite (Targ : Mnode; Targ_Type : Iir; Data : Delayed_Signal_Data) is pragma Unreferenced (Targ_Type); Assoc : O_Assoc_List; Type_Info : Type_Info_Acc; Val : O_Enode; begin Start_Association (Assoc, Ghdl_Create_Delayed_Signal); New_Association (Assoc, New_Convert_Ov (New_Value (M2Lv (Data.Pfx)), Ghdl_Signal_Ptr)); New_Association (Assoc, New_Unchecked_Address (M2Lv (Data.Targ_Val), Ghdl_Ptr_Type)); if Data.Param = Null_Iir then Val := New_Lit (New_Signed_Literal (Std_Time_Otype, 0)); else Val := Chap7.Translate_Expression (Data.Param); end if; New_Association (Assoc, Val); Type_Info := Get_Type_Info (Targ); New_Assign_Stmt (M2Lv (Targ), New_Convert_Ov (New_Function_Call (Assoc), Type_Info.Ortho_Type (Mode_Signal))); end Create_Delayed_Signal_Noncomposite; function Create_Delayed_Signal_Prepare_Composite (Targ : Mnode; Targ_Type : Iir; Data : Delayed_Signal_Data) return Delayed_Signal_Data is pragma Unreferenced (Targ_Type); Res : Delayed_Signal_Data; begin Res.Param := Data.Param; if Get_Type_Info (Targ).Type_Mode in Type_Mode_Bounded_Records then Res.Targ_Val := Stabilize (Data.Targ_Val); Res.Pfx := Stabilize (Data.Pfx); else Res.Targ_Val := Chap3.Get_Composite_Base (Data.Targ_Val); Res.Pfx := Chap3.Get_Composite_Base (Data.Pfx); end if; return Res; end Create_Delayed_Signal_Prepare_Composite; function Create_Delayed_Signal_Update_Data_Array (Data : Delayed_Signal_Data; Targ_Type : Iir; Index : O_Dnode) return Delayed_Signal_Data is begin return Delayed_Signal_Data' (Targ_Val => Chap3.Index_Base (Data.Targ_Val, Targ_Type, New_Obj_Value (Index)), Pfx => Chap3.Index_Base (Data.Pfx, Targ_Type, New_Obj_Value (Index)), Param => Data.Param); end Create_Delayed_Signal_Update_Data_Array; function Create_Delayed_Signal_Update_Data_Record (Data : Delayed_Signal_Data; Targ_Type : Iir; El : Iir_Element_Declaration) return Delayed_Signal_Data is pragma Unreferenced (Targ_Type); begin return Delayed_Signal_Data' (Targ_Val => Chap6.Translate_Selected_Element (Data.Targ_Val, El), Pfx => Chap6.Translate_Selected_Element (Data.Pfx, El), Param => Data.Param); end Create_Delayed_Signal_Update_Data_Record; procedure Create_Delayed_Signal is new Foreach_Non_Composite (Data_Type => Delayed_Signal_Data, Composite_Data_Type => Delayed_Signal_Data, Do_Non_Composite => Create_Delayed_Signal_Noncomposite, Prepare_Data_Array => Create_Delayed_Signal_Prepare_Composite, Update_Data_Array => Create_Delayed_Signal_Update_Data_Array, Prepare_Data_Record => Create_Delayed_Signal_Prepare_Composite, Update_Data_Record => Create_Delayed_Signal_Update_Data_Record); procedure Elab_Signal_Delayed_Attribute (Decl : Iir) is Sig_Type : constant Iir := Get_Type (Decl); Type_Info : constant Type_Info_Acc := Get_Info (Sig_Type); Name_Sig, Name_Val : Mnode; Pfx_Node : Mnode; Data : Delayed_Signal_Data; begin Chap6.Translate_Signal_Name (Decl, Name_Sig, Name_Val); if Is_Complex_Type (Type_Info) then Allocate_Complex_Object (Sig_Type, Alloc_System, Name_Sig); Allocate_Complex_Object (Sig_Type, Alloc_System, Name_Val); -- We cannot stabilize NAME_NODE, since Allocate_Complex_Object -- assign it. Chap6.Translate_Signal_Name (Decl, Name_Sig, Name_Val); end if; Pfx_Node := Chap6.Translate_Name (Get_Prefix (Decl), Mode_Signal); Data := Delayed_Signal_Data'(Targ_Val => Name_Val, Pfx => Pfx_Node, Param => Get_Parameter (Decl)); Create_Delayed_Signal (Name_Sig, Sig_Type, Data); end Elab_Signal_Delayed_Attribute; procedure Elab_File_Declaration (Decl : Iir_File_Declaration) is Is_Text : constant Boolean := Get_Text_File_Flag (Get_Type (Decl)); File_Name : constant Iir := Get_File_Logical_Name (Decl); Constr : O_Assoc_List; Name : Mnode; Open_Kind : Iir; Mode_Val : O_Enode; Str : O_Enode; Info : Type_Info_Acc; begin -- Elaborate the file. Name := Chap6.Translate_Name (Decl, Mode_Value); if Is_Text then Start_Association (Constr, Ghdl_Text_File_Elaborate); else Start_Association (Constr, Ghdl_File_Elaborate); Info := Get_Info (Get_Type (Decl)); if Info.B.File_Signature /= O_Dnode_Null then New_Association (Constr, New_Address (New_Obj (Info.B.File_Signature), Char_Ptr_Type)); else New_Association (Constr, New_Lit (New_Null_Access (Char_Ptr_Type))); end if; end if; New_Assign_Stmt (M2Lv (Name), New_Function_Call (Constr)); -- If file_open_information is present, open the file. if File_Name = Null_Iir then return; end if; Open_Temp; Name := Chap6.Translate_Name (Decl, Mode_Value); Open_Kind := Get_File_Open_Kind (Decl); if Open_Kind /= Null_Iir then -- VHDL 93 and later. Mode_Val := New_Convert_Ov (Chap7.Translate_Expression (Open_Kind), Ghdl_I32_Type); else -- VHDL 87. case Get_Mode (Decl) is when Iir_In_Mode => Mode_Val := New_Lit (New_Signed_Literal (Ghdl_I32_Type, 0)); when Iir_Out_Mode => Mode_Val := New_Lit (New_Signed_Literal (Ghdl_I32_Type, 1)); when others => raise Internal_Error; end case; end if; Str := Chap7.Translate_Expression (File_Name, String_Type_Definition); if Is_Text then Start_Association (Constr, Ghdl_Text_File_Open); else Start_Association (Constr, Ghdl_File_Open); end if; New_Association (Constr, M2E (Name)); New_Association (Constr, Mode_Val); New_Association (Constr, Str); New_Procedure_Call (Constr); Close_Temp; end Elab_File_Declaration; procedure Final_File_Declaration (Decl : Iir_File_Declaration) is Is_Text : constant Boolean := Get_Text_File_Flag (Get_Type (Decl)); Constr : O_Assoc_List; Name : Mnode; begin Open_Temp; Name := Chap6.Translate_Name (Decl, Mode_Value); Stabilize (Name); -- LRM 3.4.1 File Operations -- An implicit call to FILE_CLOSE exists in a subprogram body for -- every file object declared in the corresponding subprogram -- declarative part. Each such call associates a unique file object -- with the formal parameter F and is called whenever the -- corresponding subprogram completes its execution. if Is_Text then Start_Association (Constr, Ghdl_Text_File_Close); else Start_Association (Constr, Ghdl_File_Close); end if; New_Association (Constr, M2E (Name)); New_Procedure_Call (Constr); if Is_Text then Start_Association (Constr, Ghdl_Text_File_Finalize); else Start_Association (Constr, Ghdl_File_Finalize); end if; New_Association (Constr, M2E (Name)); New_Procedure_Call (Constr); Close_Temp; end Final_File_Declaration; procedure Translate_Type_Declaration (Decl : Iir) is Def : constant Iir := Get_Type_Definition (Decl); Mark : Id_Mark_Type; begin Push_Identifier_Prefix (Mark, Get_Identifier (Decl)); case Get_Kind (Def) is when Iir_Kinds_Subtype_Definition => Chap3.Translate_Subtype_Indication (Def, True); raise Internal_Error; when others => Chap3.Translate_Type_Definition (Def); end case; Pop_Identifier_Prefix (Mark); end Translate_Type_Declaration; procedure Translate_Anonymous_Type_Declaration (Decl : Iir) is Mark : Id_Mark_Type; Mark1 : Id_Mark_Type; begin Push_Identifier_Prefix (Mark, Get_Identifier (Decl)); Push_Identifier_Prefix (Mark1, "BT"); Chap3.Translate_Type_Definition (Get_Type_Definition (Decl)); Pop_Identifier_Prefix (Mark1); Pop_Identifier_Prefix (Mark); end Translate_Anonymous_Type_Declaration; procedure Translate_Subtype_Declaration (Decl : Iir_Subtype_Declaration) is Def : constant Iir := Get_Type (Decl); Mark : Id_Mark_Type; begin Push_Identifier_Prefix (Mark, Get_Identifier (Decl)); Chap3.Translate_Subtype_Definition (Def, True); Pop_Identifier_Prefix (Mark); end Translate_Subtype_Declaration; procedure Translate_Bool_Type_Declaration (Decl : Iir_Type_Declaration) is Mark : Id_Mark_Type; begin Push_Identifier_Prefix (Mark, Get_Identifier (Decl)); Chap3.Translate_Bool_Type_Definition (Get_Type_Definition (Decl)); Pop_Identifier_Prefix (Mark); end Translate_Bool_Type_Declaration; procedure Translate_Object_Alias_Declaration (Decl : Iir_Object_Alias_Declaration) is Decl_Type : constant Iir := Get_Type (Decl); Name : constant Iir := Get_Name (Decl); Info : Alias_Info_Acc; Tinfo : Type_Info_Acc; Atype : O_Tnode; Id : Var_Ident_Type; begin Chap3.Translate_Object_Subtype_Indication (Decl, True); Info := Add_Info (Decl, Kind_Alias); if Is_Signal_Name (Decl) then Info.Alias_Kind := Mode_Signal; else Info.Alias_Kind := Mode_Value; end if; Tinfo := Get_Info (Decl_Type); for Mode in Mode_Value .. Info.Alias_Kind loop case Tinfo.Type_Mode is when Type_Mode_Unbounded => -- create an object. -- At elaboration: copy base from name, copy bounds from type, -- check for matching bounds. Atype := Get_Ortho_Type (Decl_Type, Mode); when Type_Mode_Bounded_Arrays | Type_Mode_Bounded_Records | Type_Mode_Acc | Type_Mode_Bounds_Acc | Type_Mode_Protected => -- Create an object pointer. -- At elaboration: copy base from name. Atype := Tinfo.Ortho_Ptr_Type (Mode); when Type_Mode_Scalar => case Mode is when Mode_Signal => Atype := Tinfo.Ortho_Type (Mode_Signal); when Mode_Value => Atype := Tinfo.Ortho_Ptr_Type (Mode_Value); end case; when others => raise Internal_Error; end case; if Mode = Mode_Signal then Id := Create_Var_Identifier (Decl, "_SIG", 0); else Id := Create_Var_Identifier (Decl); end if; Info.Alias_Var (Mode) := Create_Var (Id, Atype); end loop; if Get_Kind (Name) = Iir_Kind_Slice_Name and then Info.Alias_Kind = Mode_Signal then -- The name subtype will be evaluated once at elaboration, as it is -- needed when direct drivers are used (in that case, the name is -- evaluated once again). declare Name_Type : constant Iir := Get_Type (Name); Mark1, Mark2 : Id_Mark_Type; begin Push_Identifier_Prefix (Mark1, Get_Identifier (Decl)); Push_Identifier_Prefix (Mark2, "AT"); Chap3.Translate_Array_Subtype (Name_Type); Pop_Identifier_Prefix (Mark2); Pop_Identifier_Prefix (Mark1); end; end if; end Translate_Object_Alias_Declaration; procedure Elab_Object_Alias_Declaration (Decl : Iir_Object_Alias_Declaration) is Decl_Type : constant Iir := Get_Type (Decl); Tinfo : constant Type_Info_Acc := Get_Info (Decl_Type); Name : constant Iir := Get_Name (Decl); Name_Type : constant Iir := Get_Type (Name); Alias_Info : constant Alias_Info_Acc := Get_Info (Decl); Name_Node : Mnode_Array; begin New_Debug_Line_Stmt (Get_Line_Number (Decl)); Chap3.Elab_Object_Subtype_Indication (Decl); Open_Temp; if Get_Kind (Name) = Iir_Kind_Slice_Name and then Alias_Info.Alias_Kind = Mode_Signal then -- See Translate_Object_Alias_Declaration. Chap3.Elab_Array_Subtype (Name_Type); end if; case Alias_Info.Alias_Kind is when Mode_Value => Name_Node (Mode_Value) := Chap6.Translate_Name (Name, Mode_Value); when Mode_Signal => Chap6.Translate_Signal_Name (Name, Name_Node (Mode_Signal), Name_Node (Mode_Value)); end case; for Mode in Mode_Value .. Alias_Info.Alias_Kind loop declare N : Mnode renames Name_Node (Mode); A : Var_Type renames Alias_Info.Alias_Var (Mode); Alias_Node : Mnode; begin -- FIXME: use subtype conversion ? case Tinfo.Type_Mode is when Type_Mode_Unbounded => Stabilize (N); Alias_Node := Stabilize (Get_Var (A, Tinfo, Mode)); Chap7.Convert_Constrained_To_Unconstrained (Alias_Node, N); when Type_Mode_Bounded_Arrays => Stabilize (N); New_Assign_Stmt (Get_Var (A), New_Convert_Ov (M2E (Chap3.Get_Composite_Base (N)), Tinfo.Ortho_Ptr_Type (Mode))); Chap3.Check_Composite_Match (Decl_Type, T2M (Decl_Type, Mode), Name_Type, N, Decl); when Type_Mode_Acc | Type_Mode_Bounds_Acc | Type_Mode_Protected => New_Assign_Stmt (Get_Var (A), M2Addr (N)); when Type_Mode_Scalar => case Mode is when Mode_Value => New_Assign_Stmt (Get_Var (A), M2Addr (N)); when Mode_Signal => New_Assign_Stmt (Get_Var (A), M2E (N)); end case; when Type_Mode_Bounded_Records => Stabilize (N); -- FIXME: Check ? New_Assign_Stmt (Get_Var (A), M2Addr (N)); when others => raise Internal_Error; end case; end; end loop; Close_Temp; end Elab_Object_Alias_Declaration; procedure Translate_Port_Chain (Parent : Iir) is Port : Iir; begin Port := Get_Port_Chain (Parent); while Port /= Null_Iir loop Create_Signal (Port); Port := Get_Chain (Port); end loop; end Translate_Port_Chain; procedure Translate_Generic_Chain (Parent : Iir) is Decl : Iir; begin Decl := Get_Generic_Chain (Parent); while Decl /= Null_Iir loop case Get_Kind (Decl) is when Iir_Kinds_Interface_Object_Declaration => Create_Object (Decl); when Iir_Kind_Interface_Package_Declaration => if Get_Generic_Map_Aspect_Chain (Decl) = Null_Iir then -- Need a formal Create_Package_Interface (Decl); else -- Instantiated. Chap2.Translate_Package_Instantiation_Declaration (Decl); end if; when Iir_Kind_Interface_Type_Declaration | Iir_Kinds_Interface_Subprogram_Declaration => null; when others => Error_Kind ("translate_generic_chain", Decl); end case; Decl := Get_Chain (Decl); end loop; end Translate_Generic_Chain; -- Create instance record for a component. procedure Translate_Component_Declaration (Decl : Iir) is Mark : Id_Mark_Type; Info : Ortho_Info_Acc; begin Info := Add_Info (Decl, Kind_Component); Push_Identifier_Prefix (Mark, Get_Identifier (Decl)); Push_Instance_Factory (Info.Comp_Scope'Access); Info.Comp_Link := Add_Instance_Factory_Field (Wki_Instance, Rtis.Ghdl_Component_Link_Type); -- Generic and ports. Translate_Generic_Chain (Decl); Translate_Port_Chain (Decl); Pop_Instance_Factory (Info.Comp_Scope'Access); New_Type_Decl (Create_Identifier ("_COMPTYPE"), Get_Scope_Type (Info.Comp_Scope)); Info.Comp_Ptr_Type := New_Access_Type (Get_Scope_Type (Info.Comp_Scope)); New_Type_Decl (Create_Identifier ("_COMPPTR"), Info.Comp_Ptr_Type); Pop_Identifier_Prefix (Mark); end Translate_Component_Declaration; procedure Translate_Declaration (Decl : Iir) is begin case Get_Kind (Decl) is when Iir_Kind_Use_Clause => null; when Iir_Kind_Configuration_Specification => null; when Iir_Kind_Disconnection_Specification => null; when Iir_Kind_Psl_Default_Clock => null; when Iir_Kind_Psl_Declaration => null; when Iir_Kind_Component_Declaration => Chap4.Translate_Component_Declaration (Decl); when Iir_Kind_Type_Declaration => -- A type declaration can be in fact a subtype declaration. Chap4.Translate_Type_Declaration (Decl); when Iir_Kind_Anonymous_Type_Declaration => Chap4.Translate_Anonymous_Type_Declaration (Decl); when Iir_Kind_Subtype_Declaration => Chap4.Translate_Subtype_Declaration (Decl); when Iir_Kind_Function_Declaration | Iir_Kind_Procedure_Declaration => raise Internal_Error; when Iir_Kind_Function_Body | Iir_Kind_Procedure_Body => null; when Iir_Kind_Protected_Type_Body => null; --when Iir_Kind_Implicit_Function_Declaration => --when Iir_Kind_Signal_Declaration -- | Iir_Kind_Interface_Signal_Declaration => -- Chap4.Create_Object (Decl); when Iir_Kind_Variable_Declaration | Iir_Kind_Constant_Declaration => Create_Object (Decl); when Iir_Kind_Signal_Declaration | Iir_Kind_Anonymous_Signal_Declaration => Create_Signal (Decl); when Iir_Kind_Object_Alias_Declaration => Translate_Object_Alias_Declaration (Decl); when Iir_Kind_Non_Object_Alias_Declaration => null; when Iir_Kind_File_Declaration => Create_File_Object (Decl); when Iir_Kind_Attribute_Declaration => -- Attribute declarations have a type mark. null; when Iir_Kind_Attribute_Specification => Chap5.Translate_Attribute_Specification (Decl); when Iir_Kind_Signal_Attribute_Declaration => declare Sig : Iir; begin Sig := Get_Signal_Attribute_Chain (Decl); while Is_Valid (Sig) loop Chap4.Create_Implicit_Signal (Sig); Sig := Get_Attr_Chain (Sig); end loop; end; when Iir_Kind_Guard_Signal_Declaration => Create_Signal (Decl); when Iir_Kind_Package_Declaration => Chap2.Translate_Package_Declaration (Decl); when Iir_Kind_Package_Body => Chap2.Translate_Package_Body (Decl); when Iir_Kind_Package_Instantiation_Declaration => Chap2.Translate_Package_Instantiation_Declaration (Decl); when Iir_Kind_Group_Template_Declaration => null; when Iir_Kind_Group_Declaration => null; when others => Error_Kind ("translate_declaration", Decl); end case; end Translate_Declaration; procedure Translate_Resolution_Function (Func : Iir) is Finfo : constant Subprg_Info_Acc := Get_Info (Func); Rinfo : constant Subprg_Resolv_Info_Acc := Finfo.Subprg_Resolv; -- Type of the resolution function parameter. El_Type : Iir; El_Info : Type_Info_Acc; Interface_List : O_Inter_List; Id : O_Ident; Itype : O_Tnode; Unused_Instance : O_Dnode; begin if Rinfo = null then -- Not a resolution function return; end if; -- Declare the procedure. Id := Create_Identifier (Func, Get_Overload_Number (Func), "_RESOLV"); Start_Procedure_Decl (Interface_List, Id, Global_Storage); -- The instance. if Subprgs.Has_Current_Subprg_Instance then Subprgs.Add_Subprg_Instance_Interfaces (Interface_List, Rinfo.Var_Instance); else -- Create a dummy instance parameter New_Interface_Decl (Interface_List, Unused_Instance, Wki_Instance, Ghdl_Ptr_Type); Rinfo.Var_Instance := Subprgs.Null_Subprg_Instance; end if; -- The signal. El_Type := Get_Type (Get_Interface_Declaration_Chain (Func)); El_Type := Get_Element_Subtype (El_Type); El_Info := Get_Info (El_Type); -- FIXME: create a function for getting the type of an interface. case El_Info.Type_Mode is when Type_Mode_Thin => Itype := El_Info.Ortho_Type (Mode_Signal); when Type_Mode_Fat => Itype := El_Info.Ortho_Ptr_Type (Mode_Signal); when Type_Mode_Unknown => raise Internal_Error; end case; New_Interface_Decl (Interface_List, Rinfo.Var_Vals, Get_Identifier ("VALS"), Itype); New_Interface_Decl (Interface_List, Rinfo.Var_Vec, Get_Identifier ("bool_vec"), Ghdl_Bool_Array_Ptr); New_Interface_Decl (Interface_List, Rinfo.Var_Vlen, Get_Identifier ("vec_len"), Ghdl_Index_Type); New_Interface_Decl (Interface_List, Rinfo.Var_Nbr_Drv, Get_Identifier ("nbr_drv"), Ghdl_Index_Type); New_Interface_Decl (Interface_List, Rinfo.Var_Nbr_Ports, Get_Identifier ("nbr_ports"), Ghdl_Index_Type); Finish_Subprogram_Decl (Interface_List, Rinfo.Resolv_Func); end Translate_Resolution_Function; type Read_Source_Kind is (Read_Port, Read_Driver); type Read_Source_Data is record Sig : Mnode; Drv_Index : O_Dnode; Kind : Read_Source_Kind; end record; procedure Read_Source_Non_Composite (Targ : Mnode; Targ_Type : Iir; Data : Read_Source_Data) is Targ_Info : constant Type_Info_Acc := Get_Info (Targ_Type); Assoc : O_Assoc_List; E : O_Enode; begin case Data.Kind is when Read_Port => Start_Association (Assoc, Ghdl_Signal_Read_Port); when Read_Driver => Start_Association (Assoc, Ghdl_Signal_Read_Driver); end case; New_Association (Assoc, New_Convert_Ov (M2E (Data.Sig), Ghdl_Signal_Ptr)); New_Association (Assoc, New_Obj_Value (Data.Drv_Index)); E := New_Convert_Ov (New_Function_Call (Assoc), Targ_Info.Ortho_Ptr_Type (Mode_Value)); New_Assign_Stmt (M2Lv (Targ), New_Value (New_Access_Element (E))); end Read_Source_Non_Composite; function Read_Source_Prepare_Data_Array (Targ: Mnode; Targ_Type : Iir; Data : Read_Source_Data) return Read_Source_Data is pragma Unreferenced (Targ, Targ_Type); begin return Data; end Read_Source_Prepare_Data_Array; function Read_Source_Prepare_Data_Record (Targ : Mnode; Targ_Type : Iir; Data : Read_Source_Data) return Read_Source_Data is pragma Unreferenced (Targ, Targ_Type); begin return Read_Source_Data'(Sig => Stabilize (Data.Sig), Drv_Index => Data.Drv_Index, Kind => Data.Kind); end Read_Source_Prepare_Data_Record; function Read_Source_Update_Data_Array (Data : Read_Source_Data; Targ_Type : Iir; Index : O_Dnode) return Read_Source_Data is begin return Read_Source_Data' (Sig => Chap3.Index_Base (Data.Sig, Targ_Type, New_Obj_Value (Index)), Drv_Index => Data.Drv_Index, Kind => Data.Kind); end Read_Source_Update_Data_Array; function Read_Source_Update_Data_Record (Data : Read_Source_Data; Targ_Type : Iir; El : Iir_Element_Declaration) return Read_Source_Data is pragma Unreferenced (Targ_Type); begin return Read_Source_Data' (Sig => Chap6.Translate_Selected_Element (Data.Sig, El), Drv_Index => Data.Drv_Index, Kind => Data.Kind); end Read_Source_Update_Data_Record; procedure Read_Signal_Source is new Foreach_Non_Composite (Data_Type => Read_Source_Data, Composite_Data_Type => Read_Source_Data, Do_Non_Composite => Read_Source_Non_Composite, Prepare_Data_Array => Read_Source_Prepare_Data_Array, Update_Data_Array => Read_Source_Update_Data_Array, Prepare_Data_Record => Read_Source_Prepare_Data_Record, Update_Data_Record => Read_Source_Update_Data_Record); procedure Translate_Resolution_Function_Body (Func : Iir) is -- Type of the resolution function parameter. Arr_Type : Iir; Base_Type : Iir; Base_Info : Type_Info_Acc; Index_Info : Index_Info_Acc; -- Type of parameter element. El_Type : Iir; El_Info : Type_Info_Acc; -- Type of the function return value. Ret_Type : Iir; Ret_Info : Type_Info_Acc; -- Type and info of the array index. Index_Type : Iir; Index_Tinfo : Type_Info_Acc; -- Local variables. Var_I : O_Dnode; Var_J : O_Dnode; Var_Length : O_Dnode; Var_Res : O_Dnode; Vals : Mnode; Res : Mnode; If_Blk : O_If_Block; Label : O_Snode; V : Mnode; Var_Bound : O_Dnode; Range_Ptr : Mnode; Var_Array : O_Dnode; Finfo : constant Subprg_Info_Acc := Get_Info (Func); Rinfo : constant Subprg_Resolv_Info_Acc := Finfo.Subprg_Resolv; Assoc : O_Assoc_List; Data : Read_Source_Data; begin if Rinfo = null then -- No resolver for this function return; end if; Ret_Type := Get_Return_Type (Func); Ret_Info := Get_Info (Ret_Type); Arr_Type := Get_Type (Get_Interface_Declaration_Chain (Func)); Base_Type := Get_Base_Type (Arr_Type); Index_Info := Get_Info (Get_Nth_Element (Get_Index_Subtype_Definition_List (Base_Type), 0)); Base_Info := Get_Info (Base_Type); El_Type := Get_Element_Subtype (Arr_Type); El_Info := Get_Info (El_Type); Index_Type := Get_Index_Type (Arr_Type, 0); Index_Tinfo := Get_Info (Index_Type); Start_Subprogram_Body (Rinfo.Resolv_Func); if Subprgs.Has_Subprg_Instance (Rinfo.Var_Instance) then Subprgs.Start_Subprg_Instance_Use (Rinfo.Var_Instance); end if; Push_Local_Factory; -- A signal. New_Var_Decl (Var_Res, Get_Identifier ("res"), O_Storage_Local, Get_Object_Type (Ret_Info, Mode_Value)); -- I, J. New_Var_Decl (Var_I, Wki_I, O_Storage_Local, Ghdl_Index_Type); New_Var_Decl (Var_J, Get_Identifier ("J"), O_Storage_Local, Ghdl_Index_Type); -- Length. New_Var_Decl (Var_Length, Wki_Length, O_Storage_Local, Ghdl_Index_Type); New_Var_Decl (Var_Bound, Get_Identifier ("BOUND"), O_Storage_Local, Base_Info.B.Bounds_Type); New_Var_Decl (Var_Array, Get_Identifier ("VARRAY"), O_Storage_Local, Base_Info.Ortho_Type (Mode_Value)); Open_Temp; case El_Info.Type_Mode is when Type_Mode_Thin => Vals := Dv2M (Rinfo.Var_Vals, El_Info, Mode_Signal); when Type_Mode_Fat => Vals := Dp2M (Rinfo.Var_Vals, El_Info, Mode_Signal); when Type_Mode_Unknown => raise Internal_Error; end case; -- * length := vec_len + nports; New_Assign_Stmt (New_Obj (Var_Length), New_Dyadic_Op (ON_Add_Ov, New_Obj_Value (Rinfo.Var_Vlen), New_Obj_Value (Rinfo.Var_Nbr_Ports))); -- Create range from length Range_Ptr := Lv2M (New_Selected_Element (New_Obj (Var_Bound), Index_Info.Index_Field), Index_Tinfo, Mode_Value, Index_Tinfo.B.Range_Type, Index_Tinfo.B.Range_Ptr_Type); Chap3.Create_Range_From_Length (Index_Type, Var_Length, Range_Ptr, Func); New_Assign_Stmt (New_Selected_Element (New_Obj (Var_Array), Base_Info.B.Bounds_Field (Mode_Value)), New_Address (New_Obj (Var_Bound), Base_Info.B.Bounds_Ptr_Type)); -- Allocate the array. Chap3.Allocate_Unbounded_Composite_Base (Alloc_Stack, Dv2M (Var_Array, Base_Info, Mode_Value), Base_Type); -- Fill the array -- 1. From ports. -- * I := 0; Init_Var (Var_I); -- * loop Start_Loop_Stmt (Label); -- * exit when I = nports; Gen_Exit_When (Label, New_Compare_Op (ON_Eq, New_Obj_Value (Var_I), New_Obj_Value (Rinfo.Var_Nbr_Ports), Ghdl_Bool_Type)); -- fill array[i] V := Chap3.Index_Base (Chap3.Get_Composite_Base (Dv2M (Var_Array, Base_Info, Mode_Value)), Base_Type, New_Obj_Value (Var_I)); Data := Read_Source_Data'(Vals, Var_I, Read_Port); Read_Signal_Source (V, El_Type, Data); -- * I := I + 1; Inc_Var (Var_I); -- * end loop; Finish_Loop_Stmt (Label); -- 2. From drivers. -- * J := 0; -- * loop -- * exit when j = var_max; -- * if vec[j] then -- -- * ptr := get_signal_driver (sig, j); -- * array[i].XXX := *ptr -- -- * i := i + 1; -- * end if; -- * J := J + 1; -- * end loop; Init_Var (Var_J); Start_Loop_Stmt (Label); Gen_Exit_When (Label, New_Compare_Op (ON_Eq, New_Obj_Value (Var_J), New_Obj_Value (Rinfo.Var_Nbr_Drv), Ghdl_Bool_Type)); Start_If_Stmt (If_Blk, New_Value (New_Indexed_Acc_Value (New_Obj (Rinfo.Var_Vec), New_Obj_Value (Var_J)))); V := Chap3.Index_Base (Chap3.Get_Composite_Base (Dv2M (Var_Array, Base_Info, Mode_Value)), Base_Type, New_Obj_Value (Var_I)); Data := Read_Source_Data'(Vals, Var_J, Read_Driver); Read_Signal_Source (V, El_Type, Data); Inc_Var (Var_I); Finish_If_Stmt (If_Blk); Inc_Var (Var_J); Finish_Loop_Stmt (Label); if Finfo.Res_Interface /= O_Dnode_Null then Res := Lo2M (Var_Res, Ret_Info, Mode_Value); if Ret_Info.Type_Mode /= Type_Mode_Fat_Array then Allocate_Complex_Object (Ret_Type, Alloc_Stack, Res); end if; end if; -- Call the resolution function. if Finfo.Use_Stack2 then Create_Temp_Stack2_Mark; end if; Start_Association (Assoc, Finfo.Subprg_Node); if Finfo.Res_Interface /= O_Dnode_Null then New_Association (Assoc, M2E (Res)); end if; Subprgs.Add_Subprg_Instance_Assoc (Assoc, Finfo.Subprg_Instance); New_Association (Assoc, New_Address (New_Obj (Var_Array), Base_Info.Ortho_Ptr_Type (Mode_Value))); if Finfo.Res_Interface = O_Dnode_Null then Res := E2M (New_Function_Call (Assoc), Ret_Info, Mode_Value); else New_Procedure_Call (Assoc); end if; if El_Type /= Ret_Type then Res := E2M (Chap7.Translate_Implicit_Conv (M2E (Res), Ret_Type, El_Type, Mode_Value, Func), El_Info, Mode_Value); end if; Chap7.Set_Driving_Value (Vals, El_Type, Res); Close_Temp; Pop_Local_Factory; if Subprgs.Has_Subprg_Instance (Rinfo.Var_Instance) then Subprgs.Finish_Subprg_Instance_Use (Rinfo.Var_Instance); end if; Finish_Subprogram_Body; end Translate_Resolution_Function_Body; procedure Translate_Declaration_Chain (Parent : Iir) is Info : Subprg_Info_Acc; El : Iir; begin El := Get_Declaration_Chain (Parent); while El /= Null_Iir loop case Get_Kind (El) is when Iir_Kind_Procedure_Declaration | Iir_Kind_Function_Declaration => -- Translate interfaces. if not Is_Implicit_Subprogram (El) and then (not Flag_Discard_Unused or else Get_Use_Flag (El)) and then not Is_Second_Subprogram_Specification (El) then Info := Add_Info (El, Kind_Subprg); Chap2.Translate_Subprogram_Interfaces (El); if Get_Kind (El) = Iir_Kind_Function_Declaration then if Get_Resolution_Function_Flag (El) then Info.Subprg_Resolv := new Subprg_Resolv_Info; end if; end if; end if; when Iir_Kind_Function_Body | Iir_Kind_Procedure_Body => null; when others => Translate_Declaration (El); end case; El := Get_Chain (El); end loop; end Translate_Declaration_Chain; procedure Translate_Statements_Chain_State_Declaration (Stmts : Iir; State_Scope : Var_Scope_Acc) is Num : Nat32; Mark : Id_Mark_Type; Locvar_Id : O_Ident; Els : O_Element_List; procedure Push_Prefix (Really_Push : Boolean := True) is Num_Img : String := Nat32'Image (Num); begin Num_Img (Num_Img'First) := 'S'; Locvar_Id := Get_Identifier (Num_Img); Num := Num + 1; if Really_Push then Push_Identifier_Prefix (Mark, Num_Img); end if; end Push_Prefix; procedure Pop_Prefix (Scope : in out Var_Scope_Type; Really_Push : Boolean := True) is Locvar_Field : O_Fnode; begin if Really_Push then Pop_Identifier_Prefix (Mark); end if; New_Union_Field (Els, Locvar_Field, Locvar_Id, Get_Scope_Type (Scope)); Set_Scope_Via_Field (Scope, Locvar_Field, State_Scope); end Pop_Prefix; Info : Ortho_Info_Acc; Stmt : Iir; Chain : Iir; Scope_Type : O_Tnode; begin Stmt := Stmts; Start_Union_Type (Els); Num := 0; while Stmt /= Null_Iir loop case Get_Kind (Stmt) is when Iir_Kind_If_Statement => if Get_Suspend_Flag (Stmt) then Chain := Stmt; while Chain /= Null_Iir loop Push_Prefix; Info := Add_Info (Chain, Kind_Locvar_State); Translate_Statements_Chain_State_Declaration (Get_Sequential_Statement_Chain (Chain), Info.Locvar_Scope'Access); Pop_Prefix (Info.Locvar_Scope); Chain := Get_Else_Clause (Chain); end loop; end if; when Iir_Kind_Case_Statement => if Get_Suspend_Flag (Stmt) then Chain := Get_Case_Statement_Alternative_Chain (Stmt); while Chain /= Null_Iir loop if not Get_Same_Alternative_Flag (Chain) then Push_Prefix; Info := Add_Info (Chain, Kind_Locvar_State); Translate_Statements_Chain_State_Declaration (Get_Associated_Chain (Chain), Info.Locvar_Scope'Access); Pop_Prefix (Info.Locvar_Scope); end if; Chain := Get_Chain (Chain); end loop; end if; when Iir_Kind_While_Loop_Statement => if Get_Suspend_Flag (Stmt) then Push_Prefix; Info := Add_Info (Stmt, Kind_Loop_State); Translate_Statements_Chain_State_Declaration (Get_Sequential_Statement_Chain (Stmt), Info.Loop_Locvar_Scope'Access); Pop_Prefix (Info.Loop_Locvar_Scope); end if; when Iir_Kind_For_Loop_Statement => if Get_Suspend_Flag (Stmt) then Push_Prefix; Info := Add_Info (Stmt, Kind_Loop_State); Push_Instance_Factory (Info.Loop_State_Scope'Access); Chap8.Translate_For_Loop_Statement_Declaration (Stmt); Translate_Statements_Chain_State_Declaration (Get_Sequential_Statement_Chain (Stmt), Info.Loop_Locvar_Scope'Access); Add_Scope_Field (Wki_Locvars, Info.Loop_Locvar_Scope); Pop_Instance_Factory (Info.Loop_State_Scope'Access); New_Type_Decl (Create_Identifier ("FORTYPE"), Get_Scope_Type (Info.Loop_State_Scope)); Pop_Prefix (Info.Loop_State_Scope); end if; when Iir_Kind_Procedure_Call_Statement => declare Call : constant Iir := Get_Procedure_Call (Stmt); Imp : constant Iir := Get_Implementation (Call); begin Vhdl.Canon.Canon_Subprogram_Call (Call); Update_Node_Infos; if Get_Suspend_Flag (Imp) then Push_Prefix; Info := Add_Info (Call, Kind_Call); Chap8.Translate_Procedure_Call_State (Call); Pop_Prefix (Info.Call_State_Scope); end if; end; when others => null; end case; Stmt := Get_Chain (Stmt); end loop; Finish_Union_Type (Els, Scope_Type); New_Type_Decl (Create_Identifier ("LOCVARTYPE"), Scope_Type); Create_Union_Scope (State_Scope.all, Scope_Type); end Translate_Statements_Chain_State_Declaration; procedure Translate_Declaration_Chain_Subprograms (Parent : Iir; What : Subprg_Translate_Kind) is -- True iff specs must be translated. Do_Specs : constant Boolean := What in Subprg_Translate_Spec; -- True iff bodies must be translated. Do_Bodies : constant Boolean := (What in Subprg_Translate_Body and then Global_Storage /= O_Storage_External); El : Iir; Infos : Chap7.Implicit_Subprogram_Infos; begin El := Get_Declaration_Chain (Parent); while El /= Null_Iir loop case Get_Kind (El) is when Iir_Kind_Procedure_Declaration | Iir_Kind_Function_Declaration => if Is_Implicit_Subprogram (El) then if Flag_Discard_Unused_Implicit and then not Get_Use_Flag (El) then case Get_Implicit_Definition (El) is when Iir_Predefined_Array_Equality | Iir_Predefined_Array_Greater | Iir_Predefined_Record_Equality => -- Used implicitly in case statement or other -- predefined equality. if Do_Specs then Chap7.Translate_Implicit_Subprogram_Spec (El, Infos); end if; if Do_Bodies then Chap7.Translate_Implicit_Subprogram_Body (El); end if; when others => null; end case; else if Do_Specs then Chap7.Translate_Implicit_Subprogram_Spec (El, Infos); end if; if Do_Bodies then Chap7.Translate_Implicit_Subprogram_Body (El); end if; end if; else -- Translate only if used. if Do_Specs and then Get_Info (El) /= null then Chap2.Translate_Subprogram_Declaration (El); Translate_Resolution_Function (El); end if; end if; when Iir_Kind_Function_Body | Iir_Kind_Procedure_Body => if Do_Bodies then -- Do not translate body if generating only specs (for -- subprograms in an entity). if not Flag_Discard_Unused or else Get_Use_Flag (Get_Subprogram_Specification (El)) then Chap2.Translate_Subprogram_Body (El); Translate_Resolution_Function_Body (Get_Subprogram_Specification (El)); end if; end if; when Iir_Kind_Type_Declaration | Iir_Kind_Anonymous_Type_Declaration => Chap3.Translate_Type_Subprograms (El, What); Chap7.Init_Implicit_Subprogram_Infos (Infos); when Iir_Kind_Protected_Type_Body => if Do_Specs then Chap3.Translate_Protected_Type_Body (El); end if; if Do_Bodies then Chap3.Translate_Protected_Type_Body_Subprograms_Spec (El); Chap3.Translate_Protected_Type_Body_Subprograms_Body (El); end if; when Iir_Kind_Package_Declaration | Iir_Kind_Package_Body => declare Mark : Id_Mark_Type; begin Push_Identifier_Prefix (Mark, Get_Identifier (El)); Translate_Declaration_Chain_Subprograms (El, What); Pop_Identifier_Prefix (Mark); end; when Iir_Kind_Package_Instantiation_Declaration => if Get_Macro_Expanded_Flag (Get_Uninstantiated_Package_Decl (El)) then declare Bod : constant Iir := Get_Instance_Package_Body (El); Mark : Id_Mark_Type; begin Push_Identifier_Prefix (Mark, Get_Identifier (El)); Translate_Declaration_Chain_Subprograms (El, What); if Is_Valid (Bod) and then Global_Storage /= O_Storage_External then Translate_Declaration_Chain_Subprograms (Bod, What); end if; Pop_Identifier_Prefix (Mark); end; end if; when others => null; end case; El := Get_Chain (El); end loop; end Translate_Declaration_Chain_Subprograms; procedure Elab_Declaration_Chain (Parent : Iir; Need_Final : out Boolean) is Decl : Iir; begin Decl := Get_Declaration_Chain (Parent); Need_Final := False; while Decl /= Null_Iir loop case Get_Kind (Decl) is when Iir_Kind_Use_Clause => null; when Iir_Kind_Component_Declaration => null; when Iir_Kind_Configuration_Specification => null; when Iir_Kind_Disconnection_Specification => Chap5.Elab_Disconnection_Specification (Decl); when Iir_Kind_Type_Declaration | Iir_Kind_Anonymous_Type_Declaration => Chap3.Elab_Type_Declaration (Decl); when Iir_Kind_Subtype_Declaration => Chap3.Elab_Subtype_Declaration (Decl); when Iir_Kind_Protected_Type_Body => null; --when Iir_Kind_Signal_Declaration => -- Chap1.Elab_Signal (Decl); when Iir_Kind_Variable_Declaration | Iir_Kind_Constant_Declaration => -- Do not call Open_Temp/Close_Temp, as objects may be created -- using alloca (which has a scope life) or on the secondary -- stack. Elab_Object (Decl); if Get_Kind (Get_Type (Decl)) = Iir_Kind_Protected_Type_Declaration then Need_Final := True; end if; when Iir_Kind_Signal_Declaration | Iir_Kind_Anonymous_Signal_Declaration => Elab_Signal_Declaration (Decl, Parent, False); when Iir_Kind_Object_Alias_Declaration => Elab_Object_Alias_Declaration (Decl); when Iir_Kind_Non_Object_Alias_Declaration => null; when Iir_Kind_File_Declaration => Elab_File_Declaration (Decl); Need_Final := True; when Iir_Kind_Attribute_Declaration => -- An attribute declaration can only have a type mark. null; when Iir_Kind_Attribute_Specification => Chap5.Elab_Attribute_Specification (Decl); when Iir_Kind_Function_Declaration | Iir_Kind_Procedure_Declaration => if not Is_Implicit_Subprogram (Decl) and then Get_Info (Decl) /= null then Chap2.Elab_Subprogram_Interfaces (Decl); end if; when Iir_Kind_Function_Body | Iir_Kind_Procedure_Body => null; when Iir_Kind_Signal_Attribute_Declaration => declare Sig : Iir; begin Sig := Get_Signal_Attribute_Chain (Decl); while Is_Valid (Sig) loop case Iir_Kinds_Signal_Attribute (Get_Kind (Sig)) is when Iir_Kind_Stable_Attribute | Iir_Kind_Quiet_Attribute | Iir_Kind_Transaction_Attribute => Elab_Signal_Attribute (Sig); when Iir_Kind_Delayed_Attribute => Elab_Signal_Delayed_Attribute (Sig); end case; Sig := Get_Attr_Chain (Sig); end loop; end; when Iir_Kind_Group_Template_Declaration | Iir_Kind_Group_Declaration => null; when Iir_Kind_Package_Declaration => Chap2.Elab_Package (Decl, Get_Package_Header (Decl)); -- FIXME: finalizer when Iir_Kind_Package_Body => declare Nested_Final : Boolean; begin Elab_Declaration_Chain (Decl, Nested_Final); Need_Final := Need_Final or Nested_Final; end; when Iir_Kind_Package_Instantiation_Declaration => -- FIXME: finalizers ? Chap2.Elab_Package_Instantiation_Declaration (Decl); when Iir_Kind_Psl_Default_Clock => null; when Iir_Kind_Psl_Declaration => null; when others => Error_Kind ("elab_declaration_chain", Decl); end case; Decl := Get_Chain (Decl); end loop; end Elab_Declaration_Chain; procedure Final_Declaration_Chain (Parent : Iir; Deallocate : Boolean) is Decl : Iir; begin Decl := Get_Declaration_Chain (Parent); while Decl /= Null_Iir loop case Get_Kind (Decl) is when Iir_Kind_File_Declaration => Final_File_Declaration (Decl); when Iir_Kind_Variable_Declaration => if Get_Kind (Get_Type (Decl)) = Iir_Kind_Protected_Type_Declaration then Fini_Protected_Object (Decl); end if; if Deallocate then Fini_Object (Decl); end if; when Iir_Kind_Constant_Declaration => if Deallocate then Fini_Object (Decl); end if; when others => null; end case; Decl := Get_Chain (Decl); end loop; end Final_Declaration_Chain; type Conv_Mode is (Conv_Mode_In, Conv_Mode_Out); -- Create subprogram for an association conversion. -- STMT is the statement/block_header containing the association. -- BLOCK is the architecture/block containing the instance. -- ASSOC is the association and MODE the conversion to work on. -- CONV_INFO is the result place holder. -- BASE_BLOCK is the base architecture/block containing the instance. -- ENTITY is the entity/component instantiated (null for block_stmt) procedure Translate_Association_Subprogram (Stmt : Iir; Block : Iir; Assoc : Iir; Inter : Iir; Mode : Conv_Mode; Conv_Info : in out Assoc_Conv_Info; Num : Iir_Int32; Base_Block : Iir; Entity : Iir) is Formal : constant Iir := Get_Association_Formal (Assoc, Inter); Actual : constant Iir := Get_Actual (Assoc); Mark2, Mark3 : Id_Mark_Type; Inter_List : O_Inter_List; In_Type, Out_Type : Iir; In_Info, Out_Info : Type_Info_Acc; El_List : O_Element_List; Block_Info : constant Block_Info_Acc := Get_Info (Base_Block); Stmt_Info : Block_Info_Acc; Entity_Info : Ortho_Info_Acc; Var_Data : O_Dnode; -- Variables for body. E : O_Enode; V : O_Dnode; V1 : O_Lnode; V_Out : Mnode; R : O_Enode; Constr : O_Assoc_List; Subprg_Info : Subprg_Info_Acc; Res : Mnode; M1 : Mnode; Imp : Iir; Func : Iir; Obj : Iir; -- Method object for function conversion Obj_Type : Iir; -- Valid only if OBJ is valid begin case Mode is when Conv_Mode_In => -- IN: from actual to formal. Push_Identifier_Prefix (Mark2, "CONVIN"); Out_Type := Get_Type (Formal); In_Type := Get_Type (Actual); Imp := Get_Actual_Conversion (Assoc); when Conv_Mode_Out => -- OUT: from formal to actual. Push_Identifier_Prefix (Mark2, "CONVOUT"); In_Type := Get_Type (Formal); Out_Type := Get_Type (Actual); Imp := Get_Formal_Conversion (Assoc); end case; -- FIXME: individual assoc -> overload. Push_Identifier_Prefix (Mark3, Get_Identifier (Get_Association_Interface (Assoc, Inter)), Num); -- Handle anonymous subtypes. Chap3.Translate_Anonymous_Subtype_Definition (Out_Type, False); Chap3.Translate_Anonymous_Subtype_Definition (In_Type, False); Out_Info := Get_Info (Out_Type); In_Info := Get_Info (In_Type); if Get_Kind (Imp) = Iir_Kind_Function_Call then Obj := Get_Method_Object (Imp); if Is_Valid (Obj) then Obj_Type := Get_Type (Obj); end if; else Obj := Null_Iir; end if; -- Start record containing data for the conversion function. Start_Record_Type (El_List); -- Add instance field. Conv_Info.Instance_Block := Base_Block; New_Record_Field (El_List, Conv_Info.Instance_Field, Wki_Instance, Block_Info.Block_Decls_Ptr_Type); -- Add instance field for the entity in case of direct instantiation. if Entity /= Null_Iir then Conv_Info.Instantiated_Entity := Entity; Entity_Info := Get_Info (Entity); declare Ptr : O_Tnode; begin if Entity_Info.Kind = Kind_Component then Ptr := Entity_Info.Comp_Ptr_Type; else Ptr := Entity_Info.Block_Decls_Ptr_Type; end if; New_Record_Field (El_List, Conv_Info.Instantiated_Field, Get_Identifier ("instantiated"), Ptr); end; else Conv_Info.Instantiated_Entity := Null_Iir; Conv_Info.Instantiated_Field := O_Fnode_Null; end if; if Obj /= Null_Iir then New_Record_Field (El_List, Conv_Info.Method_Object, Get_Identifier ("obj"), Get_Info (Obj_Type).Ortho_Ptr_Type (Mode_Value)); else Conv_Info.Method_Object := O_Fnode_Null; end if; -- Add inputs, which is a pointer to the signal. New_Record_Field (El_List, Conv_Info.In_Sig_Field, Get_Identifier ("sig_in"), Get_Object_Ptr_Type (In_Info, Mode_Signal)); New_Record_Field (El_List, Conv_Info.In_Val_Field, Get_Identifier ("val_in"), Get_Object_Ptr_Type (In_Info, Mode_Value)); -- Add output. New_Record_Field (El_List, Conv_Info.Out_Sig_Field, Get_Identifier ("sig_out"), Get_Object_Type (Out_Info, Mode_Signal)); New_Record_Field (El_List, Conv_Info.Out_Val_Field, Get_Identifier ("val_out"), Get_Object_Type (Out_Info, Mode_Value)); Finish_Record_Type (El_List, Conv_Info.Record_Type); New_Type_Decl (Create_Identifier ("DTYPE"), Conv_Info.Record_Type); Conv_Info.Record_Ptr_Type := New_Access_Type (Conv_Info.Record_Type); New_Type_Decl (Create_Identifier ("DPTR"), Conv_Info.Record_Ptr_Type); -- Declare the subprogram. Start_Procedure_Decl (Inter_List, Create_Identifier, O_Storage_Private); New_Interface_Decl (Inter_List, Var_Data, Get_Identifier ("data"), Conv_Info.Record_Ptr_Type); Finish_Subprogram_Decl (Inter_List, Conv_Info.Subprg); Start_Subprogram_Body (Conv_Info.Subprg); Push_Local_Factory; Open_Temp; -- Add an access to local block. V := Create_Temp_Init (Block_Info.Block_Decls_Ptr_Type, New_Value_Selected_Acc_Value (New_Obj (Var_Data), Conv_Info.Instance_Field)); Set_Scope_Via_Param_Ptr (Block_Info.Block_Scope, V); -- Add an access to instantiated entity. -- This may be used to do some type checks. if Conv_Info.Instantiated_Entity /= Null_Iir then declare Ptr_Type : O_Tnode; begin if Entity_Info.Kind = Kind_Component then Ptr_Type := Entity_Info.Comp_Ptr_Type; else Ptr_Type := Entity_Info.Block_Decls_Ptr_Type; end if; V := Create_Temp_Init (Ptr_Type, New_Value_Selected_Acc_Value (New_Obj (Var_Data), Conv_Info.Instantiated_Field)); if Entity_Info.Kind = Kind_Component then Set_Scope_Via_Param_Ptr (Entity_Info.Comp_Scope, V); else Set_Scope_Via_Param_Ptr (Entity_Info.Block_Scope, V); end if; end; end if; -- Add access to the instantiation-specific data. -- This is used only for anonymous subtype variables. -- FIXME: what if STMT is a binding_indication ? Stmt_Info := Get_Info (Stmt); if Stmt_Info /= null and then Has_Scope_Type (Stmt_Info.Block_Scope) then Set_Scope_Via_Field (Stmt_Info.Block_Scope, Stmt_Info.Block_Parent_Field, Get_Info (Block).Block_Scope'Access); end if; -- Read signal value. case Mode is when Conv_Mode_In => V1 := New_Selected_Acc_Value (New_Obj (Var_Data), Conv_Info.In_Val_Field); R := M2E (Lop2M (V1, In_Info, Mode_Value)); when Conv_Mode_Out => V1 := New_Selected_Acc_Value (New_Obj (Var_Data), Conv_Info.In_Sig_Field); M1 := Lop2M (V1, In_Info, Mode_Signal); M1 := Chap7.Translate_Signal_Driving_Value (M1, In_Type); R := M2E (M1); end case; case Get_Kind (Imp) is when Iir_Kind_Function_Call => Func := Get_Implementation (Imp); R := Chap7.Translate_Implicit_Conv (R, In_Type, Get_Type (Get_Interface_Declaration_Chain (Func)), Mode_Value, Assoc); -- Create result value. Subprg_Info := Get_Info (Func); if Subprg_Info.Use_Stack2 then Create_Temp_Stack2_Mark; end if; if Subprg_Info.Res_Interface /= O_Dnode_Null then -- Composite result. -- If we need to allocate, do it before starting the call! declare Res_Type : constant Iir := Get_Return_Type (Func); Res_Info : constant Type_Info_Acc := Get_Info (Res_Type); begin Res := Create_Temp (Res_Info); if Res_Info.Type_Mode /= Type_Mode_Fat_Array then Chap4.Allocate_Complex_Object (Res_Type, Alloc_Stack, Res); end if; end; end if; -- Call conversion function. Start_Association (Constr, Subprg_Info.Subprg_Node); if Subprg_Info.Res_Interface /= O_Dnode_Null then -- Composite result. New_Association (Constr, M2E (Res)); end if; if Obj /= Null_Iir then -- Protected object. New_Association (Constr, New_Value (New_Selected_Acc_Value (New_Obj (Var_Data), Conv_Info.Method_Object))); else Subprgs.Add_Subprg_Instance_Assoc (Constr, Subprg_Info.Subprg_Instance); end if; New_Association (Constr, R); if Subprg_Info.Res_Interface /= O_Dnode_Null then -- Composite result. New_Procedure_Call (Constr); E := M2E (Res); else E := New_Function_Call (Constr); end if; Res := E2M (Chap7.Translate_Implicit_Conv (E, Get_Return_Type (Func), Out_Type, Mode_Value, Imp), Get_Info (Out_Type), Mode_Value); when Iir_Kind_Type_Conversion => declare Conv_Type : constant Iir := Get_Type (Imp); begin E := Chap7.Translate_Type_Conversion (R, In_Type, Conv_Type, Assoc); E := Chap7.Translate_Implicit_Conv (E, Conv_Type, Out_Type, Mode_Value, Imp); Res := E2M (E, Get_Info (Out_Type), Mode_Value); end; when others => Error_Kind ("Translate_Association_Subprogram", Imp); end case; -- Assign signals. case Mode is when Conv_Mode_In => V1 := New_Selected_Acc_Value (New_Obj (Var_Data), Conv_Info.Out_Val_Field); V_Out := Lo2M (V1, Out_Info, Mode_Value); Chap7.Translate_Assign (V_Out, M2E (Res), Formal, Out_Type, Assoc); when Conv_Mode_Out => V1 := New_Selected_Acc_Value (New_Obj (Var_Data), Conv_Info.Out_Sig_Field); V_Out := Lo2M (V1, Out_Info, Mode_Signal); Chap7.Set_Driving_Value (V_Out, Out_Type, Res); end case; Close_Temp; if Stmt_Info /= null and then Has_Scope_Type (Stmt_Info.Block_Scope) then Clear_Scope (Stmt_Info.Block_Scope); end if; if Conv_Info.Instantiated_Entity /= Null_Iir then if Entity_Info.Kind = Kind_Component then Clear_Scope (Entity_Info.Comp_Scope); else Clear_Scope (Entity_Info.Block_Scope); end if; end if; Clear_Scope (Block_Info.Block_Scope); Pop_Local_Factory; Finish_Subprogram_Body; Pop_Identifier_Prefix (Mark3); Pop_Identifier_Prefix (Mark2); end Translate_Association_Subprogram; -- ENTITY is null for block_statement. procedure Translate_Association_Subprograms (Stmt : Iir; Block : Iir; Base_Block : Iir; Entity : Iir) is Assoc : Iir; Inter : Iir; Info : Assoc_Info_Acc; Num : Iir_Int32; begin Assoc := Get_Port_Map_Aspect_Chain (Stmt); Num := 0; if Is_Null (Entity) then Inter := Get_Port_Chain (Stmt); else Inter := Get_Port_Chain (Entity); end if; while Assoc /= Null_Iir loop if Get_Kind (Assoc) = Iir_Kind_Association_Element_By_Expression then Info := null; if Get_Actual_Conversion (Assoc) /= Null_Iir then Info := Add_Info (Assoc, Kind_Assoc); Translate_Association_Subprogram (Stmt, Block, Assoc, Inter, Conv_Mode_In, Info.Assoc_In, Num, Base_Block, Entity); Num := Num + 1; end if; if Get_Formal_Conversion (Assoc) /= Null_Iir then if Info = null then Info := Add_Info (Assoc, Kind_Assoc); end if; Translate_Association_Subprogram (Stmt, Block, Assoc, Inter, Conv_Mode_Out, Info.Assoc_Out, Num, Base_Block, Entity); Num := Num + 1; end if; end if; Next_Association_Interface (Assoc, Inter); end loop; end Translate_Association_Subprograms; -- Register conversion CONV in association between SIG_IN and SIG_OUT. -- This procedure allocates a record data (described by INFO), fill it -- with addresses of signals and register it to REG_SUBPRG. procedure Elab_Conversion (Sig_In : Iir; Sig_Out : Iir; Conv : Iir; Reg_Subprg : O_Dnode; Info : Assoc_Conv_Info; Dest_Sig : out Mnode) is Out_Type : constant Iir := Get_Type (Sig_Out); Out_Info : constant Type_Info_Acc := Get_Info (Out_Type); In_Type : constant Iir := Get_Type (Sig_In); In_Info : constant Type_Info_Acc := Get_Info (In_Type); Src_Sig : Mnode; Src_Val : Mnode; Dest_Val : Mnode; Constr : O_Assoc_List; Var_Data : O_Dnode; Data : Elab_Signal_Data; begin -- Allocate data for the subprogram. Var_Data := Create_Temp (Info.Record_Ptr_Type); New_Assign_Stmt (New_Obj (Var_Data), Gen_Alloc (Alloc_System, New_Lit (New_Sizeof (Info.Record_Type, Ghdl_Index_Type)), Info.Record_Ptr_Type)); -- Set instance. New_Assign_Stmt (New_Selected_Acc_Value (New_Obj (Var_Data), Info.Instance_Field), Get_Instance_Access (Info.Instance_Block)); -- Set instantiated unit instance (if any). if Info.Instantiated_Entity /= Null_Iir then declare Inst_Addr : O_Enode; Inst_Info : Ortho_Info_Acc; begin if Get_Kind (Info.Instantiated_Entity) = Iir_Kind_Component_Declaration then Inst_Info := Get_Info (Info.Instantiated_Entity); Inst_Addr := New_Address (Get_Instance_Ref (Inst_Info.Comp_Scope), Inst_Info.Comp_Ptr_Type); else Inst_Addr := Get_Instance_Access (Info.Instantiated_Entity); end if; New_Assign_Stmt (New_Selected_Acc_Value (New_Obj (Var_Data), Info.Instantiated_Field), Inst_Addr); end; end if; if Info.Method_Object /= O_Fnode_Null then New_Assign_Stmt (New_Selected_Acc_Value (New_Obj (Var_Data), Info.Method_Object), M2E (Chap6.Translate_Name (Get_Method_Object (Conv), Mode_Value))); end if; -- Set input. Chap6.Translate_Signal_Name (Sig_In, Src_Sig, Src_Val); Src_Sig := Stabilize (Src_Sig, True); Assign_Obj_Ptr (Lop2M (New_Selected_Acc_Value (New_Obj (Var_Data), Info.In_Sig_Field), In_Info, Mode_Signal), Src_Sig); Assign_Obj_Ptr (Lop2M (New_Selected_Acc_Value (New_Obj (Var_Data), Info.In_Val_Field), In_Info, Mode_Value), Src_Val); -- Create a copy of SIG_OUT. Dest_Sig := Lo2M (New_Selected_Acc_Value (New_Obj (Var_Data), Info.Out_Sig_Field), Out_Info, Mode_Signal); Chap4.Allocate_Complex_Object (Out_Type, Alloc_System, Dest_Sig); Dest_Val := Lo2M (New_Selected_Acc_Value (New_Obj (Var_Data), Info.Out_Val_Field), Out_Info, Mode_Value); Chap4.Allocate_Complex_Object (Out_Type, Alloc_System, Dest_Val); -- Note: NDEST will be assigned by ELAB_SIGNAL. Dest_Sig := Lo2M (New_Selected_Acc_Value (New_Obj (Var_Data), Info.Out_Sig_Field), Out_Info, Mode_Signal); Dest_Val := Lo2M (New_Selected_Acc_Value (New_Obj (Var_Data), Info.Out_Val_Field), Out_Info, Mode_Value); Data := Elab_Signal_Data'(Value => Dest_Val, Has_Val => False, Already_Resolved => True, Init_Val => Mnode_Null, Check_Null => False, If_Stmt => null); Elab_Signal (Dest_Sig, Out_Type, Data); Dest_Sig := Lo2M (New_Selected_Acc_Value (New_Obj (Var_Data), Info.Out_Sig_Field), Out_Info, Mode_Signal); Dest_Sig := Stabilize (Dest_Sig, True); -- Register. Start_Association (Constr, Reg_Subprg); New_Association (Constr, New_Lit (New_Subprogram_Address (Info.Subprg, Ghdl_Ptr_Type))); New_Association (Constr, New_Convert_Ov (New_Obj_Value (Var_Data), Ghdl_Ptr_Type)); New_Association (Constr, New_Convert_Ov (M2E (Get_Leftest_Signal (Src_Sig, Get_Type (Sig_In))), Ghdl_Signal_Ptr)); New_Association (Constr, Get_Nbr_Signals (Src_Sig, Get_Type (Sig_In))); New_Association (Constr, New_Convert_Ov (M2E (Get_Leftest_Signal (Dest_Sig, Get_Type (Sig_Out))), Ghdl_Signal_Ptr)); New_Association (Constr, Get_Nbr_Signals (Dest_Sig, Get_Type (Sig_Out))); New_Procedure_Call (Constr); end Elab_Conversion; -- In conversion: from actual to formal. procedure Elab_In_Conversion (Assoc : Iir; Formal : Iir; Ndest : out Mnode) is Assoc_Info : constant Assoc_Info_Acc := Get_Info (Assoc); begin Elab_Conversion (Get_Actual (Assoc), Formal, Get_Actual_Conversion (Assoc), Ghdl_Signal_In_Conversion, Assoc_Info.Assoc_In, Ndest); end Elab_In_Conversion; -- Out conversion: from formal to actual. procedure Elab_Out_Conversion (Assoc : Iir; Formal : Iir; Ndest : out Mnode) is -- Note: because it's an out conversion, the formal of ASSOC is set. -- Still pass INTER for coherence with Elab_In_Conversion. Assoc_Info : constant Assoc_Info_Acc := Get_Info (Assoc); begin Elab_Conversion (Formal, Get_Actual (Assoc), Get_Formal_Conversion (Assoc), Ghdl_Signal_Out_Conversion, Assoc_Info.Assoc_Out, Ndest); end Elab_Out_Conversion; -- Create a record that describe thes location of an IIR node and -- returns the address of it. function Get_Location (N : Iir) return O_Dnode is Constr : O_Record_Aggr_List; Aggr : O_Cnode; Name : Name_Id; Line : Natural; Col : Natural; C : O_Dnode; begin Files_Map.Location_To_Position (Get_Location (N), Name, Line, Col); New_Const_Decl (C, Create_Uniq_Identifier, O_Storage_Private, Ghdl_Location_Type_Node); Start_Init_Value (C); Start_Record_Aggr (Constr, Ghdl_Location_Type_Node); New_Record_Aggr_El (Constr, New_Global_Address (New_Global (Current_Filename_Node), Char_Ptr_Type)); New_Record_Aggr_El (Constr, New_Signed_Literal (Ghdl_I32_Type, Integer_64 (Line))); New_Record_Aggr_El (Constr, New_Signed_Literal (Ghdl_I32_Type, Integer_64 (Col))); Finish_Record_Aggr (Constr, Aggr); Finish_Init_Value (C, Aggr); return C; --return New_Global_Address (C, Ghdl_Location_Ptr_Node); end Get_Location; end Trans.Chap4;