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|
-- 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 <gnu.org/licenses>.
with Ada.Unchecked_Deallocation;
with Interfaces; use Interfaces;
with Ortho_Nodes; use Ortho_Nodes;
with Ortho_Ident; use Ortho_Ident;
with Vhdl.Nodes; use Vhdl.Nodes;
with Types; use Types;
package Trans is
-- Ortho type node for STD.BOOLEAN.
Std_Boolean_Type_Node : O_Tnode;
Std_Boolean_True_Node : O_Cnode;
Std_Boolean_False_Node : O_Cnode;
-- Array of STD.BOOLEAN.
Std_Boolean_Array_Type : O_Tnode;
-- Std_ulogic indexed array of STD.Boolean.
Std_Ulogic_Boolean_Array_Type : O_Tnode;
-- Ortho type node for string template pointer.
Std_String_Ptr_Node : O_Tnode;
Std_String_Node : O_Tnode;
-- Ortho type for std.standard.integer.
Std_Integer_Otype : O_Tnode;
-- Ortho type for std.standard.real.
Std_Real_Otype : O_Tnode;
-- Ortho type node for std.standard.time.
Std_Time_Otype : O_Tnode;
-- Node for the variable containing the current filename.
Current_Filename_Node : O_Dnode := O_Dnode_Null;
Current_Library_Unit : Iir := Null_Iir;
-- Global declarations.
Ghdl_Ptr_Type : O_Tnode;
Sizetype : O_Tnode;
Ghdl_I32_Type : O_Tnode;
Ghdl_I64_Type : O_Tnode;
Ghdl_Real_Type : O_Tnode;
-- Constant character.
Char_Type_Node : O_Tnode;
-- Array of char.
Chararray_Type : O_Tnode;
-- Pointer to array of char.
Char_Ptr_Type : O_Tnode;
-- Array of char ptr.
Char_Ptr_Array_Type : O_Tnode;
Char_Ptr_Array_Ptr_Type : O_Tnode;
Ghdl_Index_Type : O_Tnode;
Ghdl_Index_0 : O_Cnode;
Ghdl_Index_1 : O_Cnode;
Ghdl_Index_2 : O_Cnode;
Ghdl_Index_4 : O_Cnode;
Ghdl_Index_8 : O_Cnode;
Ghdl_Index_Ptr_Align : O_Cnode; -- Alignment of a pointer
-- Type for a file (this is in fact a index in a private table).
Ghdl_File_Index_Type : O_Tnode;
Ghdl_File_Index_Ptr_Type : O_Tnode;
-- Record containing a len and string fields.
Ghdl_Str_Len_Type_Node : O_Tnode;
Ghdl_Str_Len_Type_Len_Field : O_Fnode;
Ghdl_Str_Len_Type_Str_Field : O_Fnode;
Ghdl_Str_Len_Ptr_Node : O_Tnode;
Ghdl_Str_Len_Array_Type_Node : O_Tnode;
-- Location.
Ghdl_Location_Type_Node : O_Tnode;
Ghdl_Location_Filename_Node : O_Fnode;
Ghdl_Location_Line_Node : O_Fnode;
Ghdl_Location_Col_Node : O_Fnode;
Ghdl_Location_Ptr_Node : O_Tnode;
-- Allocate memory for a block.
Ghdl_Alloc_Ptr : O_Dnode;
-- bool type.
Ghdl_Bool_Type : O_Tnode;
type Enode_Boolean_Array is array (Boolean) of O_Cnode;
Ghdl_Bool_Nodes : Enode_Boolean_Array;
Ghdl_Bool_False_Node : O_Cnode renames Ghdl_Bool_Nodes (False);
Ghdl_Bool_True_Node : O_Cnode renames Ghdl_Bool_Nodes (True);
Ghdl_Bool_Array_Type : O_Tnode;
Ghdl_Bool_Array_Ptr : O_Tnode;
-- Size record
Ghdl_Sizes_Type : O_Tnode;
Ghdl_Sizes_Val : O_Fnode;
Ghdl_Sizes_Sig : O_Fnode;
-- Access to size.
Ghdl_Sizes_Ptr : O_Tnode;
-- Comparaison type.
Ghdl_Compare_Type : O_Tnode;
Ghdl_Compare_Lt : O_Cnode;
Ghdl_Compare_Eq : O_Cnode;
Ghdl_Compare_Gt : O_Cnode;
-- Dir type.
Ghdl_Dir_Type_Node : O_Tnode;
Ghdl_Dir_To_Node : O_Cnode;
Ghdl_Dir_Downto_Node : O_Cnode;
-- Signals.
Ghdl_Scalar_Bytes : O_Tnode;
Ghdl_Signal_Type : O_Tnode;
Ghdl_Signal_Driving_Value_Field : O_Fnode;
Ghdl_Signal_Last_Value_Field : O_Fnode;
Ghdl_Signal_Last_Event_Field : O_Fnode;
Ghdl_Signal_Last_Active_Field : O_Fnode;
Ghdl_Signal_Value_Field : O_Fnode;
Ghdl_Signal_Event_Field : O_Fnode;
Ghdl_Signal_Active_Field : O_Fnode;
Ghdl_Signal_Has_Active_Field : O_Fnode;
Ghdl_Signal_Ptr : O_Tnode;
Ghdl_Signal_Ptr_Ptr : O_Tnode;
Check_Stack_Allocation_Threshold : O_Cnode;
type Object_Kind_Type is (Mode_Value, Mode_Signal);
-- Well known identifiers.
Wki_This : O_Ident;
Wki_Size : O_Ident;
Wki_Res : O_Ident;
Wki_Dir_To : O_Ident;
Wki_Dir_Downto : O_Ident;
Wki_Left : O_Ident;
Wki_Right : O_Ident;
Wki_Dir : O_Ident;
Wki_Length : O_Ident;
Wki_I : O_Ident;
Wki_Instance : O_Ident;
Wki_Arch_Instance : O_Ident;
Wki_Name : O_Ident;
Wki_Sig : O_Ident;
Wki_Obj : O_Ident;
Wki_Rti : O_Ident;
Wki_Parent : O_Ident;
Wki_Filename : O_Ident;
Wki_Line : O_Ident;
Wki_Lo : O_Ident;
Wki_Hi : O_Ident;
Wki_Mid : O_Ident;
Wki_Cmp : O_Ident;
Wki_Upframe : O_Ident;
Wki_Frame : O_Ident;
Wki_Val : O_Ident;
Wki_L_Len : O_Ident;
Wki_R_Len : O_Ident;
Wki_Base : O_Ident;
Wki_Bounds : O_Ident;
Wki_Locvars : O_Ident;
-- ALLOCATION_KIND defines the type of memory storage.
-- ALLOC_STACK means the object is allocated on the local stack and
-- deallocated at the end of the function.
-- ALLOC_SYSTEM for object created during design elaboration and whose
-- life is infinite.
-- ALLOC_RETURN for unconstrained object returns by function.
-- ALLOC_HEAP for object created by new.
type Allocation_Kind is
(Alloc_Stack, Alloc_Return, Alloc_Heap, Alloc_System);
-- Sometimes useful to factorize code. Defines what has to be translated.
type Subprg_Translate_Kind is
(Subprg_Translate_Only_Spec,
Subprg_Translate_Spec_And_Body,
Subprg_Translate_Only_Body);
subtype Subprg_Translate_Spec is Subprg_Translate_Kind range
Subprg_Translate_Only_Spec .. Subprg_Translate_Spec_And_Body;
subtype Subprg_Translate_Body is Subprg_Translate_Kind range
Subprg_Translate_Spec_And_Body .. Subprg_Translate_Only_Body;
-- Return the value of field FIELD of lnode L that is contains
-- a pointer to a record.
-- This is equivalent to:
-- new_value (new_selected_element (new_access_element (new_value (l)),
-- field))
function New_Value_Selected_Acc_Value (L : O_Lnode; Field : O_Fnode)
return O_Enode;
function New_Selected_Acc_Value (L : O_Lnode; Field : O_Fnode)
return O_Lnode;
function New_Indexed_Acc_Value (L : O_Lnode; I : O_Enode) return O_Lnode;
-- Equivalent to new_access_element (new_value (l))
function New_Acc_Value (L : O_Lnode) return O_Lnode;
-- Return PTR + OFFSET as a RES_PTR value. The offset is the number of
-- bytes. RES_PTR must be an access type and the type of PTR must be an
-- access.
function Add_Pointer
(Ptr : O_Enode; Offset : O_Enode; Res_Ptr : O_Tnode) return O_Enode;
type Elab_Kind is (Elab_Decls, Elab_Stmts);
type O_Dnode_Elab is array (Elab_Kind) of O_Dnode;
package Chap10 is
-- There are three data storage kind: global, local or instance.
-- For example, a constant can have:
-- * a global storage when declared inside a package. This storage
-- can be accessed from any point.
-- * a local storage when declared in a subprogram. This storage
-- can be accessed from the subprogram, is created when the subprogram
-- is called and destroy when the subprogram exit.
-- * an instance storage when declared inside a process. This storage
-- can be accessed from the process via an instance pointer, is
-- created during elaboration.
--procedure Push_Global_Factory (Storage : O_Storage);
--procedure Pop_Global_Factory;
procedure Set_Global_Storage (Storage : O_Storage);
-- Set the global scope handling.
Global_Storage : O_Storage;
-- Scope for variables. This is used both to build instances (so it
-- contains the record type that contains objects declared in that
-- scope) and to use instances (it contains the path to access to these
-- objects).
type Var_Scope_Type is private;
type Var_Scope_Acc is access all Var_Scope_Type;
for Var_Scope_Acc'Storage_Size use 0;
Null_Var_Scope : constant Var_Scope_Type;
type Var_Type is private;
Null_Var : constant Var_Type;
-- Return the record type for SCOPE.
function Get_Scope_Type (Scope : Var_Scope_Type) return O_Tnode;
-- Return the size for instances of SCOPE.
function Get_Scope_Size (Scope : Var_Scope_Type) return O_Cnode;
-- Return True iff SCOPE is defined.
function Has_Scope_Type (Scope : Var_Scope_Type) return Boolean;
-- Create an empty and incomplete scope type for SCOPE using NAME.
procedure Predeclare_Scope_Type
(Scope : in out Var_Scope_Type; Name : O_Ident);
-- Declare a pointer PTR_TYPE with NAME to scope type SCOPE.
procedure Declare_Scope_Acc
(Scope : Var_Scope_Type; Name : O_Ident; Ptr_Type : out O_Tnode);
-- Start to build an instance.
-- If INSTANCE_TYPE is not O_TNODE_NULL, it must be an uncompleted
-- record type, that will be completed.
procedure Push_Instance_Factory (Scope : Var_Scope_Acc);
-- Likewise but for a frame.
procedure Push_Frame_Factory (Scope : Var_Scope_Acc;
Persistant : Boolean);
-- Manually add a field to the current instance being built.
function Add_Instance_Factory_Field (Name : O_Ident; Ftype : O_Tnode)
return O_Fnode;
-- In the scope being built, add a field NAME that contain sub-scope
-- CHILD. CHILD is modified so that accesses to CHILD objects is done
-- via SCOPE.
procedure Add_Scope_Field
(Name : O_Ident; Child : in out Var_Scope_Type);
-- Return the offset of field for CHILD in its parent scope.
function Get_Scope_Offset (Child : Var_Scope_Type; Otype : O_Tnode)
return O_Cnode;
-- Finish the building of the current instance and return the type
-- built.
procedure Pop_Instance_Factory (Scope : Var_Scope_Acc);
procedure Pop_Frame_Factory (Scope : Var_Scope_Acc);
-- Create a new scope, in which variable are created locally
-- (ie, on the stack). Always created unlocked.
procedure Push_Local_Factory;
-- Destroy a local scope.
procedure Pop_Local_Factory;
-- Create a special scope for declarations in statements. The scope
-- structure is opaque (typically a union).
procedure Create_Union_Scope
(Scope : out Var_Scope_Type; Stype : O_Tnode);
-- Set_Scope defines how to access to variables of SCOPE.
-- Variables defined in SCOPE can be accessed via field SCOPE_FIELD
-- of scope SCOPE_PARENT.
procedure Set_Scope_Via_Field
(Scope : in out Var_Scope_Type;
Scope_Field : O_Fnode; Scope_Parent : Var_Scope_Acc);
-- Variables defined in SCOPE can be accessed by dereferencing
-- field SCOPE_FIELD defined in SCOPE_PARENT.
procedure Set_Scope_Via_Field_Ptr
(Scope : in out Var_Scope_Type;
Scope_Field : O_Fnode; Scope_Parent : Var_Scope_Acc);
-- Variables/scopes defined in SCOPE can be accessed via
-- dereference of parameter SCOPE_PARAM.
procedure Set_Scope_Via_Param_Ptr
(Scope : in out Var_Scope_Type; Scope_Param : O_Dnode);
-- Variables/scopes defined in SCOPE can be accessed via DECL.
procedure Set_Scope_Via_Decl
(Scope : in out Var_Scope_Type; Decl : O_Dnode);
-- Variables/scopes defined in SCOPE can be accessed by derefencing
-- VAR.
procedure Set_Scope_Via_Var_Ptr
(Scope : in out Var_Scope_Type; Var : Var_Type);
-- Variables/scopes defined in SCOPE can be accesses through VAR.
procedure Set_Scope_Via_Var
(Scope : in out Var_Scope_Type; Var : Var_Type);
-- No more accesses to SCOPE_TYPE are allowed. Scopes must be cleared
-- before being set.
procedure Clear_Scope (Scope : in out Var_Scope_Type);
-- True if SCOPE is a null-scope (eg. was cleared).
function Is_Null (Scope : Var_Scope_Type) return Boolean;
-- Reset the identifier.
type Id_Mark_Type is limited private;
type Local_Identifier_Type is private;
procedure Reset_Identifier_Prefix;
procedure Push_Identifier_Prefix (Mark : out Id_Mark_Type;
Name : String;
Val : Iir_Int32 := 0);
procedure Push_Identifier_Prefix (Mark : out Id_Mark_Type;
Name : Name_Id;
Val : Iir_Int32 := 0);
procedure Push_Identifier_Prefix_Uniq (Mark : out Id_Mark_Type);
procedure Pop_Identifier_Prefix (Mark : in Id_Mark_Type);
-- Save/restore the local identifier number; this is used by package
-- body, which has the same prefix as the package declaration, so it
-- must continue local identifiers numbers.
-- This is used by subprogram bodies too.
procedure Save_Local_Identifier (Id : out Local_Identifier_Type);
procedure Restore_Local_Identifier (Id : Local_Identifier_Type);
-- Create an identifier from IIR node ID without the prefix.
function Create_Identifier_Without_Prefix (Id : Iir) return O_Ident;
function Create_Identifier_Without_Prefix
(Id : Iir; Str : String) return O_Ident;
function Create_Identifier_Without_Prefix
(Id : Name_Id; Str : String) return O_Ident;
-- Create an identifier from the current prefix.
function Create_Identifier return O_Ident;
-- Create an identifier from IIR node ID with prefix.
function Create_Identifier (Id : Iir; Str : String := "")
return O_Ident;
function Create_Identifier
(Id : Iir; Val : Iir_Int32; Str : String := "")
return O_Ident;
function Create_Identifier (Id : Name_Id; Str : String := "")
return O_Ident;
-- Create a prefixed identifier from a string.
function Create_Identifier (Str : String) return O_Ident;
-- Create an identifier for an elaboration procedure.
function Create_Elab_Identifier (Kind : Elab_Kind) return O_Ident;
-- Create an identifier for a variable.
-- IE, if the variable is global, prepend the prefix,
-- if the variable belong to an instance, no prefix is added.
type Var_Ident_Type is private;
function Create_Var_Identifier (Id : Iir) return Var_Ident_Type;
function Create_Var_Identifier (Id : String) return Var_Ident_Type;
function Create_Var_Identifier (Id : Iir; Str : String; Val : Natural)
return Var_Ident_Type;
function Create_Uniq_Identifier return Var_Ident_Type;
-- Create variable NAME of type VTYPE in the current scope.
-- If the current scope is the global scope, then a variable is
-- created at the top level (using decl_global_storage).
-- If the current scope is not the global scope, then a field is added
-- to the current scope.
function Create_Var
(Name : Var_Ident_Type;
Vtype : O_Tnode;
Storage : O_Storage := Global_Storage)
return Var_Type;
-- Create a global variable.
function Create_Global_Var
(Name : O_Ident; Vtype : O_Tnode; Storage : O_Storage)
return Var_Type;
-- Create a global constant and initialize it to INITIAL_VALUE.
function Create_Global_Const
(Name : O_Ident;
Vtype : O_Tnode;
Storage : O_Storage;
Initial_Value : O_Cnode)
return Var_Type;
procedure Define_Global_Const (Const : in out Var_Type; Val : O_Cnode);
-- Return the (real) reference to a variable created by Create_Var.
function Get_Var (Var : Var_Type) return O_Lnode;
-- Return a reference to the instance of type ITYPE.
function Get_Instance_Ref (Scope : Var_Scope_Type) return O_Lnode;
-- Return the address of the instance for block BLOCK.
function Get_Instance_Access (Block : Iir) return O_Enode;
-- Return the storage for the variable VAR.
function Get_Alloc_Kind_For_Var (Var : Var_Type) return Allocation_Kind;
-- Return TRUE iff VAR is stable, ie get_var (VAR) can be referenced
-- several times.
function Is_Var_Stable (Var : Var_Type) return Boolean;
-- Used only to generate RTI.
function Is_Var_Field (Var : Var_Type) return Boolean;
function Get_Var_Offset (Var : Var_Type; Otype : O_Tnode) return O_Cnode;
function Get_Var_Label (Var : Var_Type) return O_Dnode;
-- For package instantiation.
-- Associate INST_SCOPE as the instantiated scope for ORIG_SCOPE.
procedure Push_Instantiate_Var_Scope
(Inst_Scope : Var_Scope_Acc; Orig_Scope : Var_Scope_Acc);
-- Remove the association for INST_SCOPE.
procedure Pop_Instantiate_Var_Scope
(Inst_Scope : Var_Scope_Acc);
-- Get the associated instantiated scope for SCOPE.
function Instantiated_Var_Scope (Scope : Var_Scope_Acc)
return Var_Scope_Acc;
-- Create a copy of VAR using instantiated scope (if needed).
function Instantiate_Var (Var : Var_Type) return Var_Type;
-- Create a copy of SCOPE using instantiated scope (if needed).
function Instantiate_Var_Scope (Scope : Var_Scope_Type)
return Var_Scope_Type;
-- Utility function: convert identifier of N to a string, encoding
-- extended characters in extended identifiers (this is different from
-- image_identifier that simply returns the identifier, without special
-- handling of extended identifiers).
function Identifier_To_String (N : Iir) return String;
private
type Local_Identifier_Type is new Natural;
type Id_Mark_Type is record
Len : Natural;
Local_Id : Local_Identifier_Type;
end record;
type Var_Ident_Type is record
Id : O_Ident;
end record;
-- An instance contains all the data (variable, signals, constant...)
-- which are declared by an entity and an architecture.
-- (An architecture inherits the data of its entity).
--
-- The processes and implicit guard signals of an entity/architecture
-- are translated into functions. The first argument of these functions
-- is a pointer to the instance.
type Inst_Build_Kind_Type is
(
-- Variables are declared locally.
Local,
-- Variables are global.
Global,
-- A record frame is created, whose lifetime is the lifetime of the
-- subprogram. Variables become fields of the record frame, and
-- dynamic memory is allocated from the stack.
Stack_Frame,
-- A record frame is created, whose lifetime is longer than the
-- lifetime of the subprogram (for subprogram with suspension).
-- Variables become fields, and dynamic memory is allocated from the
-- secondary stack.
Persistant_Frame,
-- An instance record is created, which is never free. Dynamic
-- memory is allocated from the heap.
Instance);
type Inst_Build_Type (Kind : Inst_Build_Kind_Type);
type Inst_Build_Acc is access Inst_Build_Type;
type Inst_Build_Type (Kind : Inst_Build_Kind_Type) is record
Prev : Inst_Build_Acc;
Prev_Id_Start : Natural;
case Kind is
when Local =>
-- Previous global storage.
Prev_Global_Storage : O_Storage;
when Global =>
null;
when Instance | Stack_Frame | Persistant_Frame =>
Scope : Var_Scope_Acc;
Elements : O_Element_List;
end case;
end record;
-- Kind of variable:
-- VAR_NONE: the variable doesn't exist.
-- VAR_GLOBAL: the variable is a global variable (static or not).
-- VAR_LOCAL: the variable is on the stack.
-- VAR_SCOPE: the variable is in the instance record.
type Var_Kind is (Var_None, Var_Global, Var_Local, Var_Scope);
type Var_Type (Kind : Var_Kind := Var_None) is record
case Kind is
when Var_None =>
null;
when Var_Global
| Var_Local =>
E : O_Dnode;
when Var_Scope =>
-- To remember allocator for this variable.
I_Build_Kind : Inst_Build_Kind_Type;
I_Field : O_Fnode;
I_Scope : Var_Scope_Acc;
end case;
end record;
Null_Var : constant Var_Type := (Kind => Var_None);
type Var_Scope_Kind is (Var_Scope_None,
Var_Scope_Ptr,
Var_Scope_Decl,
Var_Scope_Field,
Var_Scope_Field_Ptr);
type Var_Scope_Type (Kind : Var_Scope_Kind := Var_Scope_None) is record
Scope_Type : O_Tnode := O_Tnode_Null;
case Kind is
when Var_Scope_None =>
-- Not set, cannot be referenced.
null;
when Var_Scope_Ptr
| Var_Scope_Decl =>
-- Instance for entity, architecture, component, subprogram,
-- resolver, process, guard function, PSL directive, PSL cover,
-- PSL assert, component instantiation elaborator
D : O_Dnode;
when Var_Scope_Field
| Var_Scope_Field_Ptr =>
-- For an entity: the architecture.
-- For an architecture: ptr to a generate subblock.
-- For a subprogram: parent frame
Field : O_Fnode;
Up_Link : Var_Scope_Acc;
end case;
end record;
Null_Var_Scope : constant Var_Scope_Type := (Scope_Type => O_Tnode_Null,
Kind => Var_Scope_None);
end Chap10;
use Chap10;
package Subprgs is
-- Subprograms instances.
--
-- Subprograms declared inside entities, architecture, blocks
-- or processes (but not inside packages) may access to data declared
-- outside the subprogram (and this with a life longer than the
-- subprogram life). These data correspond to constants, variables,
-- files, signals or types. However these data are not shared between
-- instances of the same entity, architecture... Subprograms instances
-- is the way subprograms access to these data.
-- One subprogram instance corresponds to a record.
-- Type to save an old instance builder. Subprograms may have at most
-- one instance. If they need severals (for example a protected
-- subprogram), the most recent one will have a reference to the
-- previous one.
type Subprg_Instance_Stack is limited private;
-- Declare an instance to be added for subprograms.
-- SCOPE is the scope to pass to the subprogram.
-- PTR_TYPE is a pointer to SCOPE.
-- IDENT is an identifier for the interface.
-- The previous instance is stored to PREV. It must be restored with
-- Pop_Subprg_Instance.
-- Add_Subprg_Instance_Interfaces will add an interface of name IDENT
-- and type PTR_TYPE for every instance declared by
-- Push_Subprg_Instance.
procedure Push_Subprg_Instance (Scope : Var_Scope_Acc;
Ptr_Type : O_Tnode;
Ident : O_Ident;
Prev : out Subprg_Instance_Stack);
-- Since local subprograms has a direct access to its father interfaces,
-- they do not required instances interfaces.
-- These procedures are provided to temporarly disable the addition of
-- instances interfaces. Use Pop_Subpg_Instance to restore to the
-- previous state.
procedure Clear_Subprg_Instance (Prev : out Subprg_Instance_Stack);
-- Revert of the previous subprogram.
-- Instances must be removed in opposite order they are added.
procedure Pop_Subprg_Instance (Ident : O_Ident;
Prev : Subprg_Instance_Stack);
-- True iff there is currently a subprogram instance.
function Has_Current_Subprg_Instance return Boolean;
-- Contains the subprogram interface for the instance.
type Subprg_Instance_Type is private;
Null_Subprg_Instance : constant Subprg_Instance_Type;
-- Add interfaces during the creation of a subprogram.
procedure Add_Subprg_Instance_Interfaces
(Interfaces : in out O_Inter_List; Vars : out Subprg_Instance_Type);
-- Add a field in the current factory that reference the current
-- instance.
procedure Add_Subprg_Instance_Field
(Field : out O_Fnode; Prev_Scope : out Var_Scope_Acc);
-- Associate values to the instance interface during invocation of a
-- subprogram.
procedure Add_Subprg_Instance_Assoc
(Assocs : in out O_Assoc_List; Vars : Subprg_Instance_Type);
-- Get the value to be associated to the instance interface.
function Get_Subprg_Instance (Vars : Subprg_Instance_Type)
return O_Enode;
-- True iff VARS is associated with an instance.
function Has_Subprg_Instance (Vars : Subprg_Instance_Type)
return Boolean;
-- Assign the instance field FIELD of VAR.
procedure Set_Subprg_Instance_Field
(Var : O_Dnode; Field : O_Fnode; Vars : Subprg_Instance_Type);
-- To be called at the beginning and end of a subprogram body creation.
-- Call PUSH_SCOPE for the subprogram intances.
procedure Start_Subprg_Instance_Use (Vars : Subprg_Instance_Type);
procedure Finish_Subprg_Instance_Use (Vars : Subprg_Instance_Type);
-- Call Push_Scope to reference instance from FIELD.
procedure Start_Prev_Subprg_Instance_Use_Via_Field
(Prev_Scope : Var_Scope_Acc; Field : O_Fnode);
procedure Finish_Prev_Subprg_Instance_Use_Via_Field
(Prev_Scope : Var_Scope_Acc; Field : O_Fnode);
-- Same as above, but for IIR.
procedure Create_Subprg_Instance (Interfaces : in out O_Inter_List;
Subprg : Iir);
procedure Start_Subprg_Instance_Use (Subprg : Iir);
procedure Finish_Subprg_Instance_Use (Subprg : Iir);
function Instantiate_Subprg_Instance (Inst : Subprg_Instance_Type)
return Subprg_Instance_Type;
private
type Subprg_Instance_Type is record
Inter : O_Dnode;
Inter_Type : O_Tnode;
Scope : Var_Scope_Acc;
end record;
Null_Subprg_Instance : constant Subprg_Instance_Type :=
(O_Dnode_Null, O_Tnode_Null, null);
type Subprg_Instance_Stack is record
Scope : Var_Scope_Acc;
Ptr_Type : O_Tnode;
Ident : O_Ident;
end record;
Null_Subprg_Instance_Stack : constant Subprg_Instance_Stack :=
(null, O_Tnode_Null, O_Ident_Nul);
Current_Subprg_Instance : Subprg_Instance_Stack :=
Null_Subprg_Instance_Stack;
end Subprgs;
type Ortho_Info_Kind is
(
Kind_Type,
Kind_Incomplete_Type,
Kind_Index,
Kind_Enum_Lit,
Kind_Subprg,
Kind_Operator,
Kind_Call,
Kind_Call_Assoc,
Kind_Object,
Kind_Signal,
Kind_Alias,
Kind_Iterator,
Kind_Interface,
Kind_Disconnect,
Kind_Process,
Kind_Psl_Directive,
Kind_Loop,
Kind_Loop_State,
Kind_Locvar_State,
Kind_Block,
Kind_Generate,
Kind_Component,
Kind_Field,
Kind_Package,
Kind_Package_Instance,
Kind_Config,
Kind_Assoc,
Kind_Design_File,
Kind_Library,
Kind_Expr_Eval
);
type Ortho_Info_Type_Kind is
(
Kind_Type_Scalar,
Kind_Type_Array,
Kind_Type_Record,
Kind_Type_File,
Kind_Type_Protected
);
type O_Tnode_Array is array (Object_Kind_Type) of O_Tnode;
type O_Fnode_Array is array (Object_Kind_Type) of O_Fnode;
type O_Dnode_Array is array (Object_Kind_Type) of O_Dnode;
type Var_Type_Array is array (Object_Kind_Type) of Var_Type;
type Rti_Depth_Type is new Natural range 0 .. 255;
-- Additional info for complex types.
type Complex_Type_Info is record
-- Parameters for type builders.
-- NOTE: this is only set for types (and *not* for subtypes).
Builder_Instance : Subprgs.Subprg_Instance_Type;
Builder_Layout_Param : O_Dnode;
Builder_Proc : O_Dnode := O_Dnode_Null;
end record;
type Complex_Type_Arr_Info is array (Object_Kind_Type) of Complex_Type_Info;
-- Alignment of a type.
-- This is only for Mode_Value (for Mode_Signal, the alignment is
-- Align_Ptr).
-- The size of complex types is determined at run-time, and the code to
-- compute it is generated by translation. But to know the size, the
-- alignment must also be known. It is assumed that allocators (malloc or
-- alloca) always return a pointer with the maximum alignment.
-- Eg: type cpl_rec is record
-- b : boolean;
-- v : integer_array (1 to n); -- n is a non-locally constant.
-- end record;
-- The static part contains only field 'b'. The whole size is of cpl_rec
-- is: sizeof (b) + align(v) + n * sizeof(integer) + align(cpl_rec).
-- This makes a lot of suppositions about the ABI:
-- * elementary types (including doubles) are always naturally aligned
-- * fields are aligned as their type
-- * records are aligned to their maximum field
-- * pointers have the same size
-- * finally, pointers are either 32 or 64 bits.
-- Note: deviation from the ABI may result in incorrect code as an object
-- that is statically constrained may be viewed as a complex/unbounded
-- object too.
-- Note: These suppositions are true on x86-64, on windows32.
-- but not for double on linux-x86!!
type Alignment_Type is
(
-- When alignment is not known.
Align_Undef,
-- For enumerations, integers, physical types.
Align_8, Align_16, Align_32,
-- For an access. We suppose that pointers are either 32 or 64 bits.
-- So Align_Ptr >= Align_32 but Align_64 >= Align_Ptr
Align_Ptr,
-- For float64 (floating point types), large integers or large physical
-- types.
Align_64);
function Align_Val (Algn : Alignment_Type) return O_Cnode;
-- Mode of the type; roughly speaking, this corresponds to its size
-- (for scalars) or its layout (for composite types).
-- Used to select library subprograms for signals.
type Type_Mode_Type is
(
-- Unknown mode.
Type_Mode_Unknown,
-- Boolean type, with 2 elements.
Type_Mode_B1,
-- Enumeration with at most 256 elements.
Type_Mode_E8,
-- Enumeration with more than 256 elements.
Type_Mode_E32,
-- Integer types.
Type_Mode_I32,
Type_Mode_I64,
-- Physical types.
Type_Mode_P32,
Type_Mode_P64,
-- Floating point type.
Type_Mode_F64,
-- File type.
Type_Mode_File,
-- Thin access.
Type_Mode_Acc,
-- Access to an unbounded type (this is a thin pointer to bounds
-- followed by values).
Type_Mode_Bounds_Acc,
-- Record whose size is known at compile-time. Can be a boxed record
-- if the base type is unbounded.
Type_Mode_Static_Record,
-- Constrained record, but size is not known at compile time. Can be
-- a boxed record if the base type is unbounded.
Type_Mode_Complex_Record,
-- Record with unbounded component(s).
Type_Mode_Unbounded_Record,
-- Unbounded array type (used for unconstrained arrays).
Type_Mode_Unbounded_Array,
-- Constrainted array type, with size known at compile-time.
Type_Mode_Static_Array,
-- Constrained array type (for constrained arrays), but size is
-- not known at compile time.
Type_Mode_Complex_Array,
-- Protected type (always handled as a complex type).
Type_Mode_Protected);
-- For backward source compatibility, to be removed (TODO).
Type_Mode_Fat_Array : constant Type_Mode_Type := Type_Mode_Unbounded_Array;
subtype Type_Mode_Valid is Type_Mode_Type range
Type_Mode_B1 .. Type_Mode_Type'Last;
subtype Type_Mode_Discrete is Type_Mode_Type range
Type_Mode_B1 .. Type_Mode_I64;
subtype Type_Mode_Scalar is Type_Mode_Type range
Type_Mode_B1 .. Type_Mode_F64;
subtype Type_Mode_Integers is Type_Mode_Type range
Type_Mode_I32 .. Type_Mode_I64;
-- Composite types, with the vhdl meaning: record and arrays.
subtype Type_Mode_Composite is Type_Mode_Type range
Type_Mode_Static_Record .. Type_Mode_Protected;
subtype Type_Mode_Non_Composite is Type_Mode_Type range
Type_Mode_B1 .. Type_Mode_Bounds_Acc;
-- Array types.
subtype Type_Mode_Arrays is Type_Mode_Type range
Type_Mode_Unbounded_Array .. Type_Mode_Complex_Array;
subtype Type_Mode_Bounded_Arrays is Type_Mode_Type range
Type_Mode_Static_Array .. Type_Mode_Complex_Array;
-- Record types.
subtype Type_Mode_Records is Type_Mode_Type range
Type_Mode_Static_Record .. Type_Mode_Unbounded_Record;
subtype Type_Mode_Bounded_Records is Type_Mode_Type range
Type_Mode_Static_Record .. Type_Mode_Complex_Record;
-- Thin types, ie types whose length is a scalar.
subtype Type_Mode_Thin is Type_Mode_Type range
Type_Mode_B1 .. Type_Mode_Bounds_Acc;
-- Aggregate types, ie types whose length is longer than a scalar.
subtype Type_Mode_Aggregate is Type_Mode_Type range
Type_Mode_Static_Record .. Type_Mode_Protected;
subtype Type_Mode_Fat is Type_Mode_Aggregate;
subtype Type_Mode_Unbounded is Type_Mode_Type range
Type_Mode_Unbounded_Record .. Type_Mode_Unbounded_Array;
-- Subprogram call argument mechanism.
-- In VHDL, the evaluation is strict: actual parameters are evaluated
-- before the call. This is the usual strategy of most compiled languages
-- (the main exception being Algol-68 call by name).
--
-- Call semantic is described in
-- LRM08 4.2.2.2 Constant and variable parameters.
--
-- At the semantic (and LRM level), there are two call convention: either
-- call by value or call by reference. That vocabulary should be used in
-- trans for the semantic level: call convention and call-by. According to
-- the LRM, all scalars use the call by value convention. It is possible
-- to change the actual after the call for inout parameters, using
-- pass-by value mechanism and copy-in/copy-out.
--
-- At the low-level (generated code), there are two mechanisms: either
-- pass by copy or pass by address. Again, that vocabulary should be used
-- in trans for the low-level: mechanism and pass-by.
--
-- A call by reference is always passed by address; while a call by value
-- can use a pass-by address to a copy of the value. The later being
-- used for fat accesses. With Ortho, only scalars and pointers can be
-- passed by copy.
-- In GHDL, all non-composite types use the call-by value convention, and
-- composite types use the call-by reference convention. For fat accesses,
-- a copy of the value is passed by address.
type Call_Mechanism is (Pass_By_Copy, Pass_By_Address);
type Call_Mechanism_Array is array (Object_Kind_Type) of Call_Mechanism;
-- These parameters are passed by copy, ie the argument of the subprogram
-- is the value of the object.
subtype Type_Mode_Pass_By_Copy is Type_Mode_Thin;
-- The parameters are passed by address, ie the argument of the
-- subprogram is an address to the object.
subtype Type_Mode_Pass_By_Address is Type_Mode_Aggregate;
-- Call conventions.
subtype Type_Mode_Call_By_Value is Type_Mode_Non_Composite;
subtype Type_Mode_Call_By_Reference is Type_Mode_Composite;
-- Additional informations for a resolving function.
type Subprg_Resolv_Info is record
Resolv_Func : O_Dnode;
-- Parameter nodes.
Var_Instance : Subprgs.Subprg_Instance_Type;
-- Signals
Var_Vals : O_Dnode;
-- Driving vector.
Var_Vec : O_Dnode;
-- Length of Vector.
Var_Vlen : O_Dnode;
Var_Nbr_Drv : O_Dnode;
Var_Nbr_Ports : O_Dnode;
end record;
type Subprg_Resolv_Info_Acc is access Subprg_Resolv_Info;
-- In order to support resume feature of non-sensitized processes and
-- procedure, a state variable is added to encode vertices of the control
-- flow graph (only suspendable vertices are considered: an inner loop
-- that doesn't suspend is not decomposed by this mechanism).
type State_Type is new Nat32;
-- Translation of types.
-- (Where you understand that VHDL is more complex than C...)
--
-- 1) For scalar types (integers, physical types, enumeration, floating
-- point types) and pointers, the type is fully known during analysis
-- and translation:
-- a) for integers and physical types, the size is defined by the range.
-- GHDL uses either 32-bit or 64-bit types.
-- b) for enumeration, the size is defined by the number of literals.
-- GHDL uses either 8-bit or 32-bit types.
-- c) for floating-point type, GHDL always uses 64-bit types (Float64).
-- d) for access types, GHDL uses pointers. This is slightly more
-- complex as sometimes it can be a fat pointer, which is a record
-- of two pointers. But in all cases, the size is known.
--
-- For composite subtypes (arrays and records), there are several cases:
--
-- 2) Composite types whose sub-elements are statically constrained.
-- Eg: subtype byte is bit_vector (7 downto 0);
-- Eg: subtype word is std_logic_vector (31 downto 0);
-- Eg: type my_bus is record
-- req: bit;
-- ack: bit;
-- data: byte;
-- end record;
-- This still corresponds to C: sizes and offsets are known during
-- translation.
-- However, for arrays a bound variable is created. This variable
-- contains the bounds of the array (left, right and direction) and the
-- length of each bound. This is used both for 'introspection' and for
-- conversion to fat pointers.
--
-- 3) Unbounded types. This is quite usual for parameters.
-- Eg: procedure disp_hex (v : std_logic_vector);
-- The bounds of an unbounded types are only known during execution, and
-- thus must be passed with the argument.
-- This is not the same case as an object declared with an unbounded
-- type; in that case the bounds are computed during elaboration (or
-- dynamic elaboration).
-- Eg: constant c : std_logic_vector := xxx;
--
-- For these unbounded types, the interface is translated as a fat
-- pointer, which is a structure containing a base pointer and a bound
-- pointer. The base pointer points to the data while the bound pointer
-- points to the bounds.
--
-- In some case, we need to convert from a bounded representation to an
-- unbounded representation. This happens while calling a subprogram
-- with a bounded object (and corresponds to a subtype conversion in
-- VHDL terms). In that case a fat pointer is created, using the object
-- as data and the bounds variable as the bounds. The opposite
-- conversion can also happen and we just need to check that the bounds
-- are matching and to keep only the data part.
--
-- 4) Complex types. Complex is a word used only by GHDL (not defined by
-- VHDL). You need to realize that VHDL types are more powerful than C
-- types as you can declare a type whose size is not known by the
-- compiler.
-- Eg: constant length : natural := call_to_a_complex_function(5);
-- subtype my_word is std_logic_vector (1 to length);
-- type my_bus is record
-- d : my_word;
-- req : std_logic_vector;
-- end record;
-- Clearly, LENGTH is not known during analysis. In many cases it
-- could be known during elaboration but this is not enough as such a
-- construct could also be used within subprograms using a parameter to
-- define a bound.
--
-- Because the size of these objects is not known during compilation,
-- the objects are allocated dynamically (either on the heap or on the
-- stack) during (dynamic) elaboration. They also comes with a bound
-- variable.
--
-- For arrays, the bound variable describes the index of the array and
-- the bounds of the elements (if the element is unbounded).
--
-- For records, the bound variable describes the offset and the bounds
-- of the non-static elements.
--
-- OLD:
-- Complex types.
--
-- A complex type is not a VHDL notion, but a translation notion.
-- A complex type is a composite type whose size is not known at compile
-- type. This happends in VHDL because a bound can be globally static.
-- Therefore, the length of an array may not be known at compile type,
-- and this propagates to composite types (record and array) if they
-- have such an element. This is different from unconstrained arrays.
--
-- This occurs frequently in VHDL, and could even happen within
-- subprograms.
--
-- Such types are always dynamically allocated (on the stack or on the
-- heap). They must be continuous in memory so that they could be copied
-- via memcpy/memmove.
--
-- At runtime, the size of such type is computed. A builder procedure
-- is also created to setup inner pointers. This builder procedure should
-- be called at initialization, but also after a copy.
--
-- Example:
-- 1) subtype bv_type is bit_vector (l to h);
-- variable a : bv_type
--
-- This is represented by a pointer to an array of bit. No need for
-- builder procedure, as the element type is not complex. But there
-- is a size variable for the size of bv_type
--
-- 2) type rec1_type is record
-- f1 : integer;
-- f2 : bv_type;
-- end record;
--
-- This is represented by a pointer to a record. The 'f2' field is
-- an offset to an array of bit. The size of the object is the size
-- of the record (with f2 as a pointer) + the size of bv_type.
-- The alinment of the object is the maximum alignment of its sub-
-- objects: rec1 and bv_type.
-- A builder procedure is needed to initialize the 'f2' field.
-- The memory layout is:
-- +--------------+
-- | rec1: f1 |
-- | f2 |---+
-- +--------------+ |
-- | bv_type |<--+
-- | ... |
-- +--------------+
--
-- 3) type rec2_type is record
-- g1: rec1_type;
-- g2: bv_type;
-- g3: bv_type;
-- end record;
--
-- This is represented by a pointer to a record. All the three fields
-- are offset (relative to rec2). Alignment is the maximum alignment of
-- the sub-objects (rec2, rec1, bv_type x 3).
-- The memory layout is:
-- +--------------+
-- | rec2: g1 |---+
-- | g2 |---|---+
-- | g3 |---|---|---+
-- +--------------+ | | |
-- | rec1: f1 |<--+ | |
-- | f2 |---+ | |
-- +--------------+ | | |
-- | bv_type (f2) |<--+ | |
-- | ... | | |
-- +--------------+ | |
-- | bv_type (g2) |<------+ |
-- | ... | |
-- +--------------+ |
-- | bv_type (g3) |<----------+
-- | ... |
-- +--------------+
--
-- 4) type bv_arr_type is array (natural range <>) of bv_type;
-- arr2 : bv_arr_type (1 to 4)
--
-- This should be represented by a pointer to bv_type.
-- The memory layout is:
-- +--------------+
-- | bv_type (1) |
-- | ... |
-- +--------------+
-- | bv_type (2) |
-- | ... |
-- +--------------+
-- | bv_type (3) |
-- | ... |
-- +--------------+
-- | bv_type (4) |
-- | ... |
-- +--------------+
type Assoc_Conv_Info is record
-- The subprogram created to do the conversion.
Subprg : O_Dnode;
-- The local base block
Instance_Block : Iir;
-- and its address.
Instance_Field : O_Fnode;
-- The instantiated entity (if any).
Instantiated_Entity : Iir;
-- and its address.
Instantiated_Field : O_Fnode;
-- The object if the subprogram is a method
Method_Object : O_Fnode;
In_Sig_Field : O_Fnode;
In_Val_Field : O_Fnode;
Out_Sig_Field : O_Fnode;
Out_Val_Field : O_Fnode;
Record_Type : O_Tnode;
Record_Ptr_Type : O_Tnode;
end record;
type Direct_Driver_Type is record
Sig : Iir;
Var : Var_Type;
end record;
type Direct_Driver_Arr is array (Natural range <>) of Direct_Driver_Type;
type Direct_Drivers_Acc is access Direct_Driver_Arr;
type Ortho_Info_Type (Kind : Ortho_Info_Kind);
type Ortho_Info_Acc is access Ortho_Info_Type;
subtype Type_Info_Acc is Ortho_Info_Acc (Kind_Type);
subtype Incomplete_Type_Info_Acc is Ortho_Info_Acc (Kind_Incomplete_Type);
subtype Index_Info_Acc is Ortho_Info_Acc (Kind_Index);
subtype Subprg_Info_Acc is Ortho_Info_Acc (Kind_Subprg);
subtype Operator_Info_Acc is Ortho_Info_Acc (Kind_Operator);
subtype Interface_Info_Acc is Ortho_Info_Acc (Kind_Interface);
subtype Call_Info_Acc is Ortho_Info_Acc (Kind_Call);
subtype Call_Assoc_Info_Acc is Ortho_Info_Acc (Kind_Call_Assoc);
subtype Object_Info_Acc is Ortho_Info_Acc (Kind_Object);
subtype Signal_Info_Acc is Ortho_Info_Acc (Kind_Signal);
subtype Alias_Info_Acc is Ortho_Info_Acc (Kind_Alias);
subtype Proc_Info_Acc is Ortho_Info_Acc (Kind_Process);
subtype Psl_Info_Acc is Ortho_Info_Acc (Kind_Psl_Directive);
subtype Loop_Info_Acc is Ortho_Info_Acc (Kind_Loop);
subtype Loop_State_Info_Acc is Ortho_Info_Acc (Kind_Loop_State);
subtype Block_Info_Acc is Ortho_Info_Acc (Kind_Block);
subtype Generate_Info_Acc is Ortho_Info_Acc (Kind_Generate);
subtype Comp_Info_Acc is Ortho_Info_Acc (Kind_Component);
subtype Field_Info_Acc is Ortho_Info_Acc (Kind_Field);
subtype Config_Info_Acc is Ortho_Info_Acc (Kind_Config);
subtype Assoc_Info_Acc is Ortho_Info_Acc (Kind_Assoc);
subtype Inter_Info_Acc is Ortho_Info_Acc (Kind_Interface);
subtype Design_File_Info_Acc is Ortho_Info_Acc (Kind_Design_File);
subtype Library_Info_Acc is Ortho_Info_Acc (Kind_Library);
procedure Init_Node_Infos;
procedure Update_Node_Infos;
procedure Free_Node_Infos;
procedure Set_Info (Target : Iir; Info : Ortho_Info_Acc);
procedure Clear_Info (Target : Iir);
function Get_Info (Target : Iir) return Ortho_Info_Acc;
pragma Inline (Get_Info);
-- Create an ortho_info field of kind KIND for iir node TARGET, and
-- return it.
function Add_Info (Target : Iir; Kind : Ortho_Info_Kind)
return Ortho_Info_Acc;
procedure Free_Info (Target : Iir);
procedure Free_Type_Info (Info : in out Type_Info_Acc);
function Get_Ortho_Literal (Target : Iir) return O_Cnode;
function Get_Ortho_Type (Target : Iir; Is_Sig : Object_Kind_Type)
return O_Tnode;
-- Return true is INFO is a type info for a composite type, ie:
-- * a record
-- * an array (fat or thin)
-- * a fat pointer.
function Is_Composite (Info : Type_Info_Acc) return Boolean;
pragma Inline (Is_Composite);
-- Type is bounded but layout and size are known only during elaboration.
function Is_Complex_Type (Tinfo : Type_Info_Acc) return Boolean;
-- Type size is known at compile-time.
function Is_Static_Type (Tinfo : Type_Info_Acc) return Boolean;
-- True iff TINFO is base + bounds.
function Is_Unbounded_Type (Tinfo : Type_Info_Acc) return Boolean;
pragma Inline (Is_Unbounded_Type);
type Hexstr_Type is array (Integer range 0 .. 15) of Character;
N2hex : constant Hexstr_Type := "0123456789abcdef";
type Ortho_Info_Basetype_Type
(Kind : Ortho_Info_Type_Kind := Kind_Type_Scalar) is record
-- For all types:
-- This is the maximum depth of RTI, that is the max of the depth of
-- the type itself and every types it depends on.
Rti_Max_Depth : Rti_Depth_Type;
Align : Alignment_Type;
case Kind is
when Kind_Type_Scalar =>
-- For scalar types:
-- Ortho type for the range record type.
Range_Type : O_Tnode;
-- Ortho type for an access to the range record type.
Range_Ptr_Type : O_Tnode;
-- Fields of TYPE_RANGE_TYPE.
Range_Left : O_Fnode;
Range_Right : O_Fnode;
Range_Dir : O_Fnode;
Range_Length : O_Fnode;
when Kind_Type_Array
| Kind_Type_Record =>
-- For unbounded types:
-- The base type.
Base_Type : O_Tnode_Array;
Base_Ptr_Type : O_Tnode_Array;
-- The dope vector.
-- For arrays:
-- range of indexes
-- layout of element (if element is unbounded)
-- For record:
-- offsets of complex elements
-- layout of unbounded elements
Bounds_Type : O_Tnode;
Bounds_Ptr_Type : O_Tnode;
-- For arrays with unbounded element, the layout field of the
-- bounds type.
Bounds_El : O_Fnode;
-- Size + bounds.
-- Always created for arrays, created for unbounded and complex
-- records.
Layout_Type : O_Tnode;
Layout_Ptr_Type : O_Tnode;
-- Size and bounds fields of the layout type.
Layout_Size : O_Fnode;
Layout_Bounds : O_Fnode;
-- The ortho type is a fat pointer to the base and the bounds.
-- These are the fields of the fat pointer.
Base_Field : O_Fnode_Array;
Bounds_Field : O_Fnode_Array;
-- Parameters for type builders.
-- NOTE: this is only set for types (and *not* for subtypes).
Builder : Complex_Type_Arr_Info;
when Kind_Type_File =>
-- Constant containing the signature of the file.
File_Signature : O_Dnode;
when Kind_Type_Protected =>
Prot_Scope : aliased Var_Scope_Type;
Prot_Prev_Scope : Var_Scope_Acc;
-- Init procedure for the protected type.
Prot_Init_Subprg : O_Dnode;
Prot_Init_Instance : Subprgs.Subprg_Instance_Type;
-- Final procedure.
Prot_Final_Subprg : O_Dnode;
Prot_Final_Instance : Subprgs.Subprg_Instance_Type;
-- The outer instance, if any.
Prot_Subprg_Instance_Field : O_Fnode;
-- The LOCK field in the object type
Prot_Lock_Field : O_Fnode;
end case;
end record;
type Subtype_Fields_Type is record
Tinfo : Type_Info_Acc;
Fields : O_Fnode_Array;
end record;
Subtype_Fields_Null : constant Subtype_Fields_Type :=
(Tinfo => null, Fields => (others => O_Fnode_Null));
type Subtype_Fields_Array is
array (Iir_Index32 range <>) of Subtype_Fields_Type;
type Subtype_Fields_Array_Acc is access Subtype_Fields_Array;
type Ortho_Info_Subtype_Type
(Kind : Ortho_Info_Type_Kind := Kind_Type_Scalar) is record
case Kind is
when Kind_Type_Scalar =>
-- For scalar types:
-- True if no need to check against low/high bound.
Nocheck_Low : Boolean := False;
Nocheck_Hi : Boolean := False;
-- For scalar types:
-- Range_Var is the same as its type mark (there is no need to
-- create a new range var if the range is the same).
Same_Range : Boolean := False;
-- Tree for the range record declaration.
Range_Var : Var_Type := Null_Var;
when Kind_Type_Array
| Kind_Type_Record =>
-- Variable containing the layout for a constrained type.
Composite_Layout : Var_Type;
Subtype_Owner : Type_Info_Acc := null;
Owner_Field : Field_Info_Acc := null;
-- For static record subtype: the fields of the constraints.
Rec_Fields : Subtype_Fields_Array_Acc;
when Kind_Type_File =>
null;
when Kind_Type_Protected =>
null;
end case;
end record;
-- Ortho_Info_Type_Scalar_Init : constant Ortho_Info_Type_Type :=
-- (Kind => Kind_Type_Scalar,
-- Range_Type => O_Tnode_Null,
-- Range_Ptr_Type => O_Tnode_Null,
-- Range_Var => null,
-- Range_Left => O_Fnode_Null,
-- Range_Right => O_Fnode_Null,
-- Range_Dir => O_Fnode_Null,
-- Range_Length => O_Fnode_Null);
Ortho_Info_Basetype_Array_Init : constant Ortho_Info_Basetype_Type :=
(Kind => Kind_Type_Array,
Rti_Max_Depth => 0,
Align => Align_Undef,
Base_Type => (O_Tnode_Null, O_Tnode_Null),
Base_Ptr_Type => (O_Tnode_Null, O_Tnode_Null),
Bounds_Type => O_Tnode_Null,
Bounds_Ptr_Type => O_Tnode_Null,
Bounds_El => O_Fnode_Null,
Layout_Type => O_Tnode_Null,
Layout_Ptr_Type => O_Tnode_Null,
Layout_Size => O_Fnode_Null,
Layout_Bounds => O_Fnode_Null,
Base_Field => (O_Fnode_Null, O_Fnode_Null),
Bounds_Field => (O_Fnode_Null, O_Fnode_Null),
Builder => (others => (Builder_Instance => Subprgs.Null_Subprg_Instance,
Builder_Layout_Param => O_Dnode_Null,
Builder_Proc => O_Dnode_Null)));
Ortho_Info_Subtype_Array_Init : constant Ortho_Info_Subtype_Type :=
(Kind => Kind_Type_Array,
Composite_Layout => Null_Var,
Subtype_Owner => null,
Owner_Field => null,
Rec_Fields => null);
Ortho_Info_Basetype_Record_Init : constant Ortho_Info_Basetype_Type :=
(Kind => Kind_Type_Record,
Rti_Max_Depth => 0,
Align => Align_Undef,
Base_Type => (O_Tnode_Null, O_Tnode_Null),
Base_Ptr_Type => (O_Tnode_Null, O_Tnode_Null),
Bounds_Type => O_Tnode_Null,
Bounds_Ptr_Type => O_Tnode_Null,
Bounds_El => O_Fnode_Null,
Layout_Type => O_Tnode_Null,
Layout_Ptr_Type => O_Tnode_Null,
Layout_Size => O_Fnode_Null,
Layout_Bounds => O_Fnode_Null,
Base_Field => (O_Fnode_Null, O_Fnode_Null),
Bounds_Field => (O_Fnode_Null, O_Fnode_Null),
Builder => (others => (Builder_Instance => Subprgs.Null_Subprg_Instance,
Builder_Layout_Param => O_Dnode_Null,
Builder_Proc => O_Dnode_Null)));
Ortho_Info_Subtype_Record_Init : constant Ortho_Info_Subtype_Type :=
(Kind => Kind_Type_Record,
Composite_Layout => Null_Var,
Subtype_Owner => null,
Owner_Field => null,
Rec_Fields => null);
Ortho_Info_Basetype_File_Init : constant Ortho_Info_Basetype_Type :=
(Kind => Kind_Type_File,
Rti_Max_Depth => 0,
Align => Align_Undef,
File_Signature => O_Dnode_Null);
Ortho_Info_Basetype_Prot_Init : constant Ortho_Info_Basetype_Type :=
(Kind => Kind_Type_Protected,
Rti_Max_Depth => 0,
Align => Align_Undef,
Prot_Scope => Null_Var_Scope,
Prot_Prev_Scope => null,
Prot_Init_Subprg => O_Dnode_Null,
Prot_Init_Instance => Subprgs.Null_Subprg_Instance,
Prot_Final_Subprg => O_Dnode_Null,
Prot_Subprg_Instance_Field => O_Fnode_Null,
Prot_Final_Instance => Subprgs.Null_Subprg_Instance,
Prot_Lock_Field => O_Fnode_Null);
-- In order to unify and have a common handling of Enode/Lnode/Dnode,
-- let's introduce Mnode (yes, another node).
--
-- Mnodes can be converted to Enode/Lnode via the M2xx functions. If
-- an Mnode are referenced more than once, they must be stabilized (this
-- will create a new variable if needed as Enode and Lnode can be
-- referenced only once).
--
-- An Mnode is a typed union, containing either an Lnode or a Enode.
-- See Mstate for a description of the union.
-- The real data is contained insisde a record, so that the discriminant
-- can be changed.
type Mnode;
-- State of an Mmode.
type Mstate is
(
-- The Mnode contains an Enode for a value.
-- This Mnode can be used only once.
Mstate_Ev,
-- The Mnode contains an Enode for a pointer.
-- This Mnode can be used only once.
Mstate_Ep,
-- The Mnode contains an Lnode representing a value.
-- This Lnode can be used only once.
Mstate_Lv,
-- The Mnode contains an Lnode representing a pointer.
-- This Lnode can be used only once.
Mstate_Lp,
-- The Mnode contains an Dnode for a variable representing a value.
-- This Dnode may be used several times.
Mstate_Dv,
-- The Mnode contains an Dnode for a variable representing a pointer.
-- This Dnode may be used several times.
Mstate_Dp,
-- Null Mnode.
Mstate_Null,
-- The Mnode is invalid (such as already used).
Mstate_Bad);
type Mnode1 (State : Mstate := Mstate_Bad) is record
-- Additionnal informations about the objects: kind and type.
K : Object_Kind_Type;
T : Type_Info_Acc;
-- Ortho type of the object.
Vtype : O_Tnode;
-- Type for a pointer to the object.
Ptype : O_Tnode;
case State is
when Mstate_Ev =>
Ev : O_Enode;
when Mstate_Ep =>
Ep : O_Enode;
when Mstate_Lv =>
Lv : O_Lnode;
when Mstate_Lp =>
Lp : O_Lnode;
when Mstate_Dv =>
Dv : O_Dnode;
when Mstate_Dp =>
Dp : O_Dnode;
when Mstate_Bad
| Mstate_Null =>
null;
end case;
end record;
--pragma Pack (Mnode1);
type Mnode is record
M1 : Mnode1;
end record;
-- Null Mnode.
Mnode_Null : constant Mnode := Mnode'(M1 => (State => Mstate_Null,
K => Mode_Value,
Ptype => O_Tnode_Null,
Vtype => O_Tnode_Null,
T => null));
type Mnode_Array is array (Object_Kind_Type) of Mnode;
-- Object kind of a Mnode
function Get_Object_Kind (M : Mnode) return Object_Kind_Type;
-- Transform VAR to Mnode.
function Get_Var
(Var : Var_Type; Vtype : Type_Info_Acc; Mode : Object_Kind_Type)
return Mnode;
-- Likewise, but VAR is a pointer to the value.
function Get_Varp
(Var : Var_Type; Vtype : Type_Info_Acc; Mode : Object_Kind_Type)
return Mnode;
-- Return a stabilized node for M.
-- The former M is not usuable anymore.
function Stabilize (M : Mnode; Can_Copy : Boolean := False) return Mnode;
-- Stabilize M.
procedure Stabilize (M : in out Mnode);
-- If M is not stable, create a variable containing the value of M.
-- M must be scalar (or access).
function Stabilize_Value (M : Mnode) return Mnode;
-- Create a temporary of type INFO and kind KIND.
function Create_Temp (Info : Type_Info_Acc;
Kind : Object_Kind_Type := Mode_Value)
return Mnode;
function Get_Type_Info (M : Mnode) return Type_Info_Acc;
pragma Inline (Get_Type_Info);
-- Creation of Mnodes.
function E2M (E : O_Enode; T : Type_Info_Acc; Kind : Object_Kind_Type)
return Mnode;
function E2M (E : O_Enode;
T : Type_Info_Acc;
Kind : Object_Kind_Type;
Vtype : O_Tnode;
Ptype : O_Tnode)
return Mnode;
-- From a Lnode, general form (can be used for ranges, bounds, base...)
function Lv2M (L : O_Lnode;
T : Type_Info_Acc;
Kind : Object_Kind_Type;
Vtype : O_Tnode;
Ptype : O_Tnode)
return Mnode;
-- From a Lnode, only for values.
function Lv2M (L : O_Lnode; T : Type_Info_Acc; Kind : Object_Kind_Type)
return Mnode;
-- From a Lnode that designates a pointer, general form.
function Lp2M (L : O_Lnode;
T : Type_Info_Acc;
Kind : Object_Kind_Type;
Vtype : O_Tnode;
Ptype : O_Tnode)
return Mnode;
-- From a Lnode that designates a pointer to a value.
function Lp2M (L : O_Lnode; T : Type_Info_Acc; Kind : Object_Kind_Type)
return Mnode;
-- From a variable declaration, general form.
function Dv2M (D : O_Dnode;
T : Type_Info_Acc;
Kind : Object_Kind_Type;
Vtype : O_Tnode;
Ptype : O_Tnode)
return Mnode;
-- From a variable for a value.
function Dv2M (D : O_Dnode; T : Type_Info_Acc; Kind : Object_Kind_Type)
return Mnode;
-- From a pointer variable, general form.
function Dp2M (D : O_Dnode;
T : Type_Info_Acc;
Kind : Object_Kind_Type;
Vtype : O_Tnode;
Ptype : O_Tnode)
return Mnode;
-- From a pointer to a value variable.
function Dp2M (D : O_Dnode; T : Type_Info_Acc; Kind : Object_Kind_Type)
return Mnode;
function M2Lv (M : Mnode) return O_Lnode;
function M2Lp (M : Mnode) return O_Lnode;
function M2Dp (M : Mnode) return O_Dnode;
function M2Dv (M : Mnode) return O_Dnode;
function T2M (Atype : Iir; Kind : Object_Kind_Type) return Mnode;
function M2E (M : Mnode) return O_Enode;
function M2Addr (M : Mnode) return O_Enode;
-- function Is_Null (M : Mnode) return Boolean is
-- begin
-- return M.M1.State = Mstate_Null;
-- end Is_Null;
function Is_Stable (M : Mnode) return Boolean;
function Varv2M (Var : Var_Type;
Var_Type : Type_Info_Acc;
Mode : Object_Kind_Type;
Vtype : O_Tnode;
Ptype : O_Tnode)
return Mnode;
-- Convert a Lnode for a sub object to an MNODE.
function Lo2M (L : O_Lnode; Vtype : Type_Info_Acc; Mode : Object_Kind_Type)
return Mnode;
function Lo2M (D : O_Dnode; Vtype : Type_Info_Acc; Mode : Object_Kind_Type)
return Mnode;
type Ortho_Info_Type (Kind : Ortho_Info_Kind) is record
-- For a simple memory management: use mark and sweep to free all infos.
Mark : Boolean := False;
case Kind is
when Kind_Type =>
-- Mode of the type.
Type_Mode : Type_Mode_Type := Type_Mode_Unknown;
-- If true, the type is (still) incomplete.
Type_Incomplete : Boolean := False;
-- For array only. True if the type is constrained with locally
-- static bounds. May have non locally-static bounds in some
-- of its sub-element (ie being a complex type).
Type_Locally_Constrained : Boolean := False;
-- Ortho node which represents the type.
-- Type -> Ortho type
-- scalar -> scalar
-- bounded record (complex or not) -> record
-- constrained non-complex array -> constrained array
-- constrained complex array -> the element
-- unbounded array or record -> fat pointer
-- access to unconstrained array -> fat pointer
-- access (others) -> access
-- file -> file_index_type
-- protected -> instance
Ortho_Type : O_Tnode_Array;
-- Ortho pointer to the type. This is always an access to the
-- ortho_type.
Ortho_Ptr_Type : O_Tnode_Array;
-- More info according to the type.
B : Ortho_Info_Basetype_Type;
S : Ortho_Info_Subtype_Type;
-- Run-time information.
Type_Rti : O_Dnode := O_Dnode_Null;
when Kind_Incomplete_Type =>
-- The declaration of the incomplete type.
Incomplete_Type : Iir;
when Kind_Index =>
-- For index_subtype_declaration, the field containing
-- the bounds of that index, in the array bounds record.
Index_Field : O_Fnode;
when Kind_Field =>
-- For element whose type is static: field in the record.
-- For element whose type is not static: offset field in the
-- bounds.
Field_Node : O_Fnode_Array := (O_Fnode_Null, O_Fnode_Null);
-- The field in the layout record for the layout of the
-- element (for unbounded element).
Field_Bound : O_Fnode := O_Fnode_Null;
when Kind_Enum_Lit =>
-- Ortho tree which represents the expression, used for
-- enumeration literals.
Lit_Node : O_Cnode;
when Kind_Subprg =>
-- True if the function can return a value stored in the secondary
-- stack. In this case, the caller must deallocate the area
-- allocated by the callee when the value was used.
Use_Stack2 : Boolean := False;
-- Subprogram declaration node.
Subprg_Node : O_Dnode;
-- For a function:
-- If the return value is not composite, then this field
-- must be O_DNODE_NULL.
-- If the return value is a composite type, then the caller must
-- give to the callee an area to put the result. This area is
-- given via an (hidden to the user) interface. Furthermore,
-- the function is translated into a procedure.
-- For a procedure:
-- Interface for parameters.
Res_Interface : O_Dnode := O_Dnode_Null;
-- Field in the frame for a pointer to the PARAMS structure. This
-- is necessary when nested subprograms need to access to
-- paramters. of this subprogram.
Subprg_Params_Var : Var_Type := Null_Var;
-- For a procedure, record containing the parameters.
Subprg_Params_Type : O_Tnode := O_Tnode_Null;
Subprg_Params_Ptr : O_Tnode := O_Tnode_Null;
-- Field in the parameter struct for the suspend state. Also the
-- suspend state is not a parameter, it is initialized by the
-- caller.
Subprg_State_Field : O_Fnode := O_Fnode_Null;
-- Field in the parameter struct for local variables.
Subprg_Locvars_Field : O_Fnode := O_Fnode_Null;
Subprg_Locvars_Scope : aliased Var_Scope_Type;
-- Access to the declarations within this subprogram.
Subprg_Frame_Scope : aliased Var_Scope_Type;
-- Instances for the subprograms.
Subprg_Instance : Subprgs.Subprg_Instance_Type :=
Subprgs.Null_Subprg_Instance;
Subprg_Resolv : Subprg_Resolv_Info_Acc := null;
-- Local identifier number, set by spec, continued by body.
Subprg_Local_Id : Local_Identifier_Type;
-- If set, return should be converted into exit out of the
-- SUBPRG_EXIT loop and the value should be assigned to
-- SUBPRG_RESULT, if any.
Subprg_Exit : O_Snode := O_Snode_Null;
Subprg_Result : O_Dnode := O_Dnode_Null;
when Kind_Operator =>
-- For an implicit subprogram like type operators or file
-- subprograms.
-- Use secondary stack (not referenced).
Operator_Stack2 : Boolean := False;
-- True if the body was generated. Many operators share the same
-- subprogram.
Operator_Body : Boolean := False;
-- Subprogram declaration node.
Operator_Node : O_Dnode;
-- Instances for the subprograms.
Operator_Instance : Subprgs.Subprg_Instance_Type :=
Subprgs.Null_Subprg_Instance;
-- Parameters
Operator_Left, Operator_Right : O_Dnode;
Operator_Res : O_Dnode;
when Kind_Call =>
Call_State_Scope : aliased Var_Scope_Type;
Call_State_Mark : Var_Type := Null_Var;
Call_Params_Var : Var_Type := Null_Var;
when Kind_Call_Assoc =>
-- Variable containing a reference to the actual, for scalar
-- copyout. The value is passed in the parameter.
Call_Assoc_Ref : Var_Type := Null_Var;
-- Variable containing the value, the bounds and the fat vector.
Call_Assoc_Value : Var_Type_Array := (others => Null_Var);
Call_Assoc_Bounds : Var_Type := Null_Var;
Call_Assoc_Fat : Var_Type_Array := (others => Null_Var);
when Kind_Object =>
-- For constants: set when the object is defined as a constant.
Object_Static : Boolean;
-- The object itself.
Object_Var : Var_Type;
-- RTI constant for the object.
Object_Rti : O_Dnode := O_Dnode_Null;
when Kind_Signal =>
-- The current value of the signal.
-- Also the initial value of collapsed ports.
Signal_Val : Var_Type := Null_Var;
-- Pointer to the value, for ports.
Signal_Valp : Var_Type := Null_Var;
-- A pointer to the signal (contains meta data).
Signal_Sig : Var_Type;
-- Direct driver for signal (if any).
Signal_Driver : Var_Type := Null_Var;
-- RTI constant for the object.
Signal_Rti : O_Dnode := O_Dnode_Null;
-- Function to compute the value of object (used for implicit
-- guard signal declaration).
Signal_Function : O_Dnode := O_Dnode_Null;
when Kind_Alias =>
Alias_Var : Var_Type_Array;
Alias_Kind : Object_Kind_Type;
when Kind_Iterator =>
-- True if the range should be copied as it may change during
-- the loop.
Iterator_Range_Copy : Boolean;
-- Iterator variable.
Iterator_Var : Var_Type;
-- Iterator right bound (used only if the iterator is a range
-- expression).
Iterator_Right : Var_Type;
-- Iterator range pointer (used only if the iterator is not a
-- range expression).
Iterator_Range : Var_Type;
when Kind_Interface =>
-- Call mechanism (by copy or by address) for the interface.
Interface_Mechanism : Call_Mechanism_Array;
-- Ortho declaration for the interface. If not null, there is
-- a corresponding ortho parameter for the interface. While
-- translating nested subprograms (that are unnested),
-- Interface_Field may be set to the corresponding field in the
-- FRAME record. So:
-- Decl: not null, Field: null: parameter
-- Decl: not null, Field: not null: parameter with a copy in
-- the FRAME record.
-- Decl: null, Field: null: not possible
-- Decl: null, Field: not null: field in RESULT record
Interface_Decl : O_Dnode_Array := (others => O_Dnode_Null);
-- Field of the PARAMS record for arguments of procedure.
-- In that case, Interface_Node must be null.
Interface_Field : O_Fnode_Array := (others => O_Fnode_Null);
when Kind_Expr_Eval =>
-- Result of an evaluation.
Expr_Eval : Mnode;
when Kind_Disconnect =>
-- Variable which contains the time_expression of the
-- disconnection specification
Disconnect_Var : Var_Type;
when Kind_Process =>
Process_Scope : aliased Var_Scope_Type;
-- Subprogram for the process.
Process_Subprg : O_Dnode;
-- Variable (in the frame) containing the current state (a
-- number) used to resume the process.
Process_State : Var_Type := Null_Var;
-- Union containing local declarations for statements.
Process_Locvar_Scope : aliased Var_Scope_Type;
-- List of drivers if Flag_Direct_Drivers.
Process_Drivers : Direct_Drivers_Acc := null;
-- RTI for the process.
Process_Rti_Const : O_Dnode := O_Dnode_Null;
when Kind_Psl_Directive =>
Psl_Scope : aliased Var_Scope_Type;
-- Procedure for the state machine.
Psl_Proc_Subprg : O_Dnode;
-- Procedure for finalization. Handles EOS.
Psl_Proc_Final_Subprg : O_Dnode;
-- Type of the state vector.
Psl_Vect_Type : O_Tnode;
-- State vector variable.
Psl_Vect_Var : Var_Type;
-- Counter variable (nbr of failures or coverage)
Psl_Count_Var : Var_Type;
-- RTI for the process.
Psl_Rti_Const : O_Dnode := O_Dnode_Null;
when Kind_Loop =>
-- Labels for the loop.
-- Used for exit/next from while-loop, and to exit from for-loop.
Label_Exit : O_Snode;
-- Used to next from for-loop, with an exit statment.
Label_Next : O_Snode;
when Kind_Loop_State =>
-- Likewise but for a suspendable loop.
-- State next: evaluate condition for a while-loop, update
-- iterator for a for-loop.
Loop_State_Next : State_Type;
-- Body of a for-loop, not used for a while-loop.
Loop_State_Body: State_Type;
-- State after the loop.
Loop_State_Exit : State_Type;
-- Access to declarations of the iterator.
Loop_State_Scope : aliased Var_Scope_Type;
Loop_Locvar_Scope : aliased Var_Scope_Type;
when Kind_Locvar_State =>
Locvar_Scope : aliased Var_Scope_Type;
when Kind_Block =>
-- Access to declarations of this block.
Block_Scope : aliased Var_Scope_Type;
-- Instance type (ortho record) for declarations contained in the
-- block/entity/architecture.
Block_Decls_Ptr_Type : O_Tnode;
-- For Entity: field in the instance type containing link to
-- parent.
-- For an instantiation: link in the parent block to the instance.
Block_Link_Field : O_Fnode;
-- For an entity: must be o_fnode_null.
-- For an architecture: the entity field.
-- For a block, a component or a generate block: field in the
-- parent instance which contains the declarations for this
-- block.
Block_Parent_Field : O_Fnode;
-- For a generate block: field in the block providing a chain to
-- the previous block (note: this may not be the parent, but
-- is a parent).
Block_Origin_Field : O_Fnode;
-- For an iterative block: boolean field set when the block
-- is configured. This is used to check if the block was already
-- configured since index and slice are not compelled to be
-- locally static.
Block_Configured_Field : O_Fnode;
-- For iterative generate block: array of instances.
Block_Decls_Array_Type : O_Tnode;
Block_Decls_Array_Ptr_Type : O_Tnode;
-- For if-generate generate statement body: the identifier of the
-- body. Used to know which block_configuration applies to the
-- block.
Block_Id : Nat32;
-- Subprograms which elaborates the block (for entity or arch).
Block_Elab_Subprg : O_Dnode_Elab;
-- Size of the block instance.
Block_Instance_Size : O_Dnode;
-- Only for an entity: procedure that elaborate the packages this
-- units depend on. That must be done before elaborating the
-- entity and before evaluating default expressions in generics.
Block_Elab_Pkg_Subprg : O_Dnode;
-- RTI constant for the block.
Block_Rti_Const : O_Dnode := O_Dnode_Null;
when Kind_Generate =>
-- Like Block_Parent_Field: field in the instance for the
-- sub-block. Always a Ghdl_Ptr_Type, as there are many possible
-- types for the sub-block instance (if/case generate).
Generate_Parent_Field : O_Fnode;
-- Identifier number of the generate statement body. Used for
-- configuring sub-block, and for grt to index the rti.
Generate_Body_Id : O_Fnode;
-- RTI for the generate statement.
Generate_Rti_Const : O_Dnode := O_Dnode_Null;
when Kind_Component =>
-- How to access to component interfaces.
Comp_Scope : aliased Var_Scope_Type;
-- Instance for the component.
Comp_Ptr_Type : O_Tnode;
-- Field containing a pointer to the instance link.
Comp_Link : O_Fnode;
-- RTI for the component.
Comp_Rti_Const : O_Dnode;
when Kind_Config =>
-- Subprogram that configure the block.
Config_Subprg : O_Dnode;
Config_Instance : O_Dnode;
when Kind_Package =>
-- Subprogram which elaborate the package spec/body.
-- External units should call the body elaborator.
-- The spec elaborator is called only from the body elaborator.
Package_Elab_Spec_Subprg : O_Dnode;
Package_Elab_Body_Subprg : O_Dnode;
-- Instance for the elaborators.
Package_Elab_Spec_Instance : Subprgs.Subprg_Instance_Type;
Package_Elab_Body_Instance : Subprgs.Subprg_Instance_Type;
-- Variable set to true when the package is elaborated.
Package_Elab_Var : Var_Type;
-- RTI constant for the package.
Package_Rti_Const : O_Dnode;
-- Access to declarations of the spec.
Package_Spec_Scope : aliased Var_Scope_Type;
-- Instance type for uninstantiated package
Package_Spec_Ptr_Type : O_Tnode;
Package_Body_Scope : aliased Var_Scope_Type;
Package_Body_Ptr_Type : O_Tnode;
-- Field to the spec within the body.
Package_Spec_Field : O_Fnode;
-- Local id, set by package declaration, continued by package
-- body.
Package_Local_Id : Local_Identifier_Type;
when Kind_Package_Instance =>
-- The variables containing the instance. There are two variables
-- for interface package: one for the spec, one for the body.
-- For package instantiation, only the variable for the body is
-- used. The variable for spec is added so that packages with
-- package interfaces don't need to know the body of their
-- interfaces.
Package_Instance_Spec_Var : Var_Type;
Package_Instance_Body_Var : Var_Type;
-- Elaboration procedure for the instance.
Package_Instance_Elab_Subprg : O_Dnode;
Package_Instance_Spec_Scope : aliased Var_Scope_Type;
Package_Instance_Body_Scope : aliased Var_Scope_Type;
when Kind_Assoc =>
-- Association informations.
Assoc_In : Assoc_Conv_Info;
Assoc_Out : Assoc_Conv_Info;
when Kind_Design_File =>
Design_Filename : O_Dnode;
when Kind_Library =>
Library_Rti_Const : O_Dnode;
end case;
end record;
procedure Unchecked_Deallocation is new Ada.Unchecked_Deallocation
(Name => Ortho_Info_Acc, Object => Ortho_Info_Type);
package Helpers is
-- Generate code to initialize a ghdl_index_type variable V to 0.
procedure Init_Var (V : O_Dnode);
-- Generate code to increment/decrement a ghdl_index_type variable V.
procedure Inc_Var (V : O_Dnode);
procedure Dec_Var (V : O_Dnode);
-- Generate code to exit from loop LABEL iff COND is true.
procedure Gen_Exit_When (Label : O_Snode; Cond : O_Enode);
-- Low-level stack2 mark and release.
procedure Set_Stack2_Mark (Var : O_Lnode);
procedure Release_Stack2 (Var : O_Lnode);
-- Create a region for temporary variables. The region is only created
-- on demand (at the first Create_Temp*), so you must be careful not
-- to nest with control statement. For example, the following
-- sequence is not correct:
-- Open_Temp
-- Start_If_Stmt
-- ... Create_Temp ...
-- Finish_If_Stmt
-- Close_Temp
-- Because the first Create_Temp is within the if statement, the
-- declare block will be created within the if statement, and must
-- have been closed before the end of the if statement.
procedure Open_Temp;
-- Create a temporary variable.
function Create_Temp (Atype : O_Tnode) return O_Dnode;
-- Create a temporary variable of ATYPE and initialize it with VALUE.
function Create_Temp_Init (Atype : O_Tnode; Value : O_Enode)
return O_Dnode;
-- Create a temporary variable of ATYPE and initialize it with the
-- address of NAME.
function Create_Temp_Ptr (Atype : O_Tnode; Name : O_Lnode)
return O_Dnode;
function Create_Temp_Bounds (Tinfo : Type_Info_Acc) return Mnode;
-- Create a mark in the temporary region for the stack2.
-- FIXME: maybe a flag must be added to CLOSE_TEMP where it is known
-- stack2 can be released.
procedure Create_Temp_Stack2_Mark;
-- Close the temporary region.
procedure Close_Temp;
-- Like Open_Temp, but will never create a declare region. To be used
-- only within a subprogram, to use the declare region of the
-- subprogram.
procedure Open_Local_Temp;
procedure Close_Local_Temp;
-- Return TRUE if stack2 will be released. Used for fine-tuning only
-- (return statement).
function Has_Stack2_Mark return Boolean;
-- Manually release stack2. Used for fine-tuning only.
procedure Stack2_Release;
-- Used only in procedure calls to disable the release of stack2, as
-- it might be part of the state of the call. Must be called just after
-- Open_Temp.
procedure Disable_Stack2_Release;
-- Free all old temp.
-- Used only to free memory.
procedure Free_Old_Temp;
-- Return a ghdl_index_type literal for NUM.
function New_Index_Lit (Num : Unsigned_64) return O_Cnode;
-- Create a uniq identifier.
subtype Uniq_Identifier_String is String (1 .. 11);
function Create_Uniq_Identifier return Uniq_Identifier_String;
function Create_Uniq_Identifier return O_Ident;
end Helpers;
end Trans;
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