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|
-- Mcode back-end for ortho - Expressions and control handling.
-- Copyright (C) 2006 Tristan Gingold
--
-- GHDL 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, or (at your option) any later
-- version.
--
-- GHDL 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 GCC; see the file COPYING. If not, write to the Free
-- Software Foundation, 59 Temple Place - Suite 330, Boston, MA
-- 02111-1307, USA.
with Ada.Text_IO;
with Ada.Unchecked_Deallocation;
with Tables;
with Ortho_Code.Types; use Ortho_Code.Types;
with Ortho_Code.Consts; use Ortho_Code.Consts;
with Ortho_Code.Decls; use Ortho_Code.Decls;
with Ortho_Code.Debug; use Ortho_Code.Debug;
with Ortho_Code.Abi; use Ortho_Code.Abi;
with Ortho_Code.Disps;
with Ortho_Code.Opts;
with Ortho_Code.Flags;
package body Ortho_Code.Exprs is
type Enode_Pad is mod 256;
type Enode_Common is record
Kind : OE_Kind; -- about 1 byte (6 bits)
Reg : O_Reg; -- 1 byte
Mode : Mode_Type; -- 4 bits
Ref : Boolean;
Flag1 : Boolean;
Flag2 : Boolean;
Flag3 : Boolean;
Pad : Enode_Pad;
Arg1 : O_Enode;
Arg2 : O_Enode;
Info : Int32;
end record;
pragma Pack (Enode_Common);
for Enode_Common'Size use 4*32;
for Enode_Common'Alignment use 4;
package Enodes is new Tables
(Table_Component_Type => Enode_Common,
Table_Index_Type => O_Enode,
Table_Low_Bound => 2,
Table_Initial => 1024);
function Get_Expr_Kind (Enode : O_Enode) return OE_Kind is
begin
return Enodes.Table (Enode).Kind;
end Get_Expr_Kind;
function Get_Expr_Mode (Enode : O_Enode) return Mode_Type is
begin
return Enodes.Table (Enode).Mode;
end Get_Expr_Mode;
function Get_Enode_Type (Enode : O_Enode) return O_Tnode is
begin
return O_Tnode (Enodes.Table (Enode).Info);
end Get_Enode_Type;
function Get_Expr_Reg (Enode : O_Enode) return O_Reg is
begin
return Enodes.Table (Enode).Reg;
end Get_Expr_Reg;
procedure Set_Expr_Reg (Enode : O_Enode; Reg : O_Reg) is
begin
Enodes.Table (Enode).Reg := Reg;
end Set_Expr_Reg;
function Get_Expr_Operand (Enode : O_Enode) return O_Enode is
begin
return Enodes.Table (Enode).Arg1;
end Get_Expr_Operand;
procedure Set_Expr_Operand (Enode : O_Enode; Val : O_Enode) is
begin
Enodes.Table (Enode).Arg1 := Val;
end Set_Expr_Operand;
function Get_Expr_Left (Enode : O_Enode) return O_Enode is
begin
return Enodes.Table (Enode).Arg1;
end Get_Expr_Left;
function Get_Expr_Right (Enode : O_Enode) return O_Enode is
begin
return Enodes.Table (Enode).Arg2;
end Get_Expr_Right;
procedure Set_Expr_Left (Enode : O_Enode; Val : O_Enode) is
begin
Enodes.Table (Enode).Arg1 := Val;
end Set_Expr_Left;
procedure Set_Expr_Right (Enode : O_Enode; Val : O_Enode) is
begin
Enodes.Table (Enode).Arg2 := Val;
end Set_Expr_Right;
function Get_Expr_Low (Cst : O_Enode) return Uns32 is
begin
return To_Uns32 (Int32 (Enodes.Table (Cst).Arg1));
end Get_Expr_Low;
function Get_Expr_High (Cst : O_Enode) return Uns32 is
begin
return To_Uns32 (Int32 (Enodes.Table (Cst).Arg2));
end Get_Expr_High;
function Get_Assign_Target (Enode : O_Enode) return O_Enode is
begin
return Enodes.Table (Enode).Arg2;
end Get_Assign_Target;
procedure Set_Assign_Target (Enode : O_Enode; Targ : O_Enode) is
begin
Enodes.Table (Enode).Arg2 := Targ;
end Set_Assign_Target;
function Get_Expr_Lit (Lit : O_Enode) return O_Cnode is
begin
return O_Cnode (Enodes.Table (Lit).Arg1);
end Get_Expr_Lit;
function Get_Conv_Type (Enode : O_Enode) return O_Tnode is
begin
return O_Tnode (Enodes.Table (Enode).Arg2);
end Get_Conv_Type;
-- Leave node corresponding to the entry.
function Get_Entry_Leave (Enode : O_Enode) return O_Enode is
begin
return Enodes.Table (Enode).Arg1;
end Get_Entry_Leave;
procedure Set_Entry_Leave (Enode : O_Enode; Leave : O_Enode) is
begin
Enodes.Table (Enode).Arg1 := Leave;
end Set_Entry_Leave;
function Get_Jump_Label (Enode : O_Enode) return O_Enode is
begin
return Enodes.Table (Enode).Arg2;
end Get_Jump_Label;
procedure Set_Jump_Label (Enode : O_Enode; Label : O_Enode) is
begin
Enodes.Table (Enode).Arg2 := Label;
end Set_Jump_Label;
function Get_Addr_Object (Enode : O_Enode) return O_Dnode is
begin
return O_Dnode (Enodes.Table (Enode).Arg1);
end Get_Addr_Object;
function Get_Addrl_Frame (Enode : O_Enode) return O_Enode is
begin
return Enodes.Table (Enode).Arg2;
end Get_Addrl_Frame;
procedure Set_Addrl_Frame (Enode : O_Enode; Frame : O_Enode) is
begin
Enodes.Table (Enode).Arg2 := Frame;
end Set_Addrl_Frame;
function Get_Call_Subprg (Enode : O_Enode) return O_Dnode is
begin
return O_Dnode (Enodes.Table (Enode).Arg1);
end Get_Call_Subprg;
function Get_Stack_Adjust (Enode : O_Enode) return Int32 is
begin
return Int32 (Enodes.Table (Enode).Arg1);
end Get_Stack_Adjust;
procedure Set_Stack_Adjust (Enode : O_Enode; Off : Int32) is
begin
Enodes.Table (Enode).Arg1 := O_Enode (Off);
end Set_Stack_Adjust;
function Get_Arg_Link (Enode : O_Enode) return O_Enode is
begin
return Enodes.Table (Enode).Arg2;
end Get_Arg_Link;
function Get_Block_Decls (Blk : O_Enode) return O_Dnode is
begin
return O_Dnode (Enodes.Table (Blk).Arg2);
end Get_Block_Decls;
function Get_Block_Parent (Blk : O_Enode) return O_Enode is
begin
return Enodes.Table (Blk).Arg1;
end Get_Block_Parent;
function Get_Block_Has_Alloca (Blk : O_Enode) return Boolean is
begin
return Enodes.Table (Blk).Flag1;
end Get_Block_Has_Alloca;
procedure Set_Block_Has_Alloca (Blk : O_Enode; Flag : Boolean) is
begin
Enodes.Table (Blk).Flag1 := Flag;
end Set_Block_Has_Alloca;
function Get_End_Beg (Blk : O_Enode) return O_Enode is
begin
return Enodes.Table (Blk).Arg1;
end Get_End_Beg;
function Get_Label_Info (Label : O_Enode) return Int32 is
begin
return Int32 (Enodes.Table (Label).Arg2);
end Get_Label_Info;
procedure Set_Label_Info (Label : O_Enode; Info : Int32) is
begin
Enodes.Table (Label).Arg2 := O_Enode (Info);
end Set_Label_Info;
function Get_Label_Block (Label : O_Enode) return O_Enode is
begin
return Enodes.Table (Label).Arg1;
end Get_Label_Block;
function Get_Spill_Info (Spill : O_Enode) return Int32 is
begin
return Int32 (Enodes.Table (Spill).Arg2);
end Get_Spill_Info;
procedure Set_Spill_Info (Spill : O_Enode; Info : Int32) is
begin
Enodes.Table (Spill).Arg2 := O_Enode (Info);
end Set_Spill_Info;
-- Get the statement link.
function Get_Stmt_Link (Stmt : O_Enode) return O_Enode is
begin
return O_Enode (Enodes.Table (Stmt).Info);
end Get_Stmt_Link;
procedure Set_Stmt_Link (Stmt : O_Enode; Next : O_Enode) is
begin
Enodes.Table (Stmt).Info := Int32 (Next);
end Set_Stmt_Link;
function Get_BB_Next (Stmt : O_Enode) return O_Enode is
begin
return Enodes.Table (Stmt).Arg1;
end Get_BB_Next;
pragma Unreferenced (Get_BB_Next);
procedure Set_BB_Next (Stmt : O_Enode; Next : O_Enode) is
begin
Enodes.Table (Stmt).Arg1 := Next;
end Set_BB_Next;
function Get_BB_Number (Stmt : O_Enode) return Int32 is
begin
return Int32 (Enodes.Table (Stmt).Arg2);
end Get_BB_Number;
function Get_Loop_Level (Stmt : O_Enode) return Int32 is
begin
return Int32 (Enodes.Table (Stmt).Arg1);
end Get_Loop_Level;
procedure Set_Loop_Level (Stmt : O_Enode; Level : Int32) is
begin
Enodes.Table (Stmt).Arg1 := O_Enode (Level);
end Set_Loop_Level;
procedure Set_Case_Branch (C : O_Enode; Branch : O_Enode) is
begin
Enodes.Table (C).Arg2 := Branch;
end Set_Case_Branch;
procedure Set_Case_Branch_Choice (Branch : O_Enode; Choice : O_Enode) is
begin
Enodes.Table (Branch).Arg1 := Choice;
end Set_Case_Branch_Choice;
function Get_Case_Branch_Choice (Branch : O_Enode) return O_Enode is
begin
return Enodes.Table (Branch).Arg1;
end Get_Case_Branch_Choice;
procedure Set_Case_Choice_Link (Choice : O_Enode; N_Choice : O_Enode) is
begin
Enodes.Table (Choice).Info := Int32 (N_Choice);
end Set_Case_Choice_Link;
function Get_Case_Choice_Link (Choice : O_Enode) return O_Enode is
begin
return O_Enode (Enodes.Table (Choice).Info);
end Get_Case_Choice_Link;
function Get_Ref_Field (Ref : O_Enode) return O_Fnode is
begin
return O_Fnode (Enodes.Table (Ref).Arg2);
end Get_Ref_Field;
function Get_Ref_Index (Ref : O_Enode) return O_Enode is
begin
return Enodes.Table (Ref).Arg2;
end Get_Ref_Index;
function Get_Expr_Line_Number (Stmt : O_Enode) return Int32 is
begin
return Int32 (Enodes.Table (Stmt).Arg1);
end Get_Expr_Line_Number;
function Get_Intrinsic_Operation (Stmt : O_Enode) return Int32 is
begin
return Int32 (Enodes.Table (Stmt).Arg1);
end Get_Intrinsic_Operation;
Last_Stmt : O_Enode := O_Enode_Null;
procedure Link_Stmt (Stmt : O_Enode) is
begin
-- Expect a real statement.
pragma Assert (Stmt /= O_Enode_Null);
-- Must be withint a subprogram.
pragma Assert (Last_Stmt /= O_Enode_Null);
Set_Stmt_Link (Last_Stmt, Stmt);
Last_Stmt := Stmt;
end Link_Stmt;
function New_Enode (Kind : OE_Kind;
Rtype : O_Tnode;
Arg1 : O_Enode;
Arg2 : O_Enode) return O_Enode
is
Mode : Mode_Type;
begin
Mode := Get_Type_Mode (Rtype);
Enodes.Append (Enode_Common'(Kind => Kind,
Reg => 0,
Mode => Mode,
Ref => False,
Flag1 => False,
Flag2 => False,
Flag3 => False,
Pad => 0,
Arg1 => Arg1,
Arg2 => Arg2,
Info => Int32 (Rtype)));
return Enodes.Last;
end New_Enode;
function New_Enode (Kind : OE_Kind;
Mode : Mode_Type;
Rtype : O_Tnode;
Arg1 : O_Enode;
Arg2 : O_Enode) return O_Enode
is
begin
Enodes.Append (Enode_Common'(Kind => Kind,
Reg => 0,
Mode => Mode,
Ref => False,
Flag1 => False,
Flag2 => False,
Flag3 => False,
Pad => 0,
Arg1 => Arg1,
Arg2 => Arg2,
Info => Int32 (Rtype)));
return Enodes.Last;
end New_Enode;
procedure New_Enode_Stmt (Kind : OE_Kind; Arg1 : O_Enode; Arg2 : O_Enode)
is
begin
Enodes.Append (Enode_Common'(Kind => Kind,
Reg => 0,
Mode => Mode_Nil,
Ref => False,
Flag1 => False,
Flag2 => False,
Flag3 => False,
Pad => 0,
Arg1 => Arg1,
Arg2 => Arg2,
Info => 0));
Link_Stmt (Enodes.Last);
end New_Enode_Stmt;
procedure New_Enode_Stmt
(Kind : OE_Kind; Mode : Mode_Type; Arg1 : O_Enode; Arg2 : O_Enode)
is
begin
Enodes.Append (Enode_Common'(Kind => Kind,
Reg => 0,
Mode => Mode,
Ref => False,
Flag1 => False,
Flag2 => False,
Flag3 => False,
Pad => 0,
Arg1 => Arg1,
Arg2 => Arg2,
Info => 0));
Link_Stmt (Enodes.Last);
end New_Enode_Stmt;
Bb_Num : Int32 := 0;
Last_Bb : O_Enode := O_Enode_Null;
procedure Create_BB is
begin
New_Enode_Stmt (OE_BB, Mode_Nil, O_Enode_Null, O_Enode (Bb_Num));
if Last_Bb /= O_Enode_Null then
Set_BB_Next (Last_Bb, Enodes.Last);
end if;
Last_Bb := Enodes.Last;
Bb_Num := Bb_Num + 1;
end Create_BB;
procedure Start_BB is
begin
if Flags.Flag_Opt_BB then
Create_BB;
end if;
end Start_BB;
pragma Inline (Start_BB);
procedure Check_Ref (E : O_Enode) is
begin
if Enodes.Table (E).Ref then
raise Syntax_Error;
end if;
Enodes.Table (E).Ref := True;
end Check_Ref;
procedure Check_Ref (E : O_Lnode) is
begin
Check_Ref (O_Enode (E));
end Check_Ref;
procedure Check_Value_Type (Val : O_Enode; Vtype : O_Tnode) is
begin
if Get_Enode_Type (Val) /= Vtype then
raise Syntax_Error;
end if;
end Check_Value_Type;
function New_Const_U32 (Val : Uns32; Vtype : O_Tnode) return O_Enode
is
begin
return New_Enode (OE_Const, Vtype,
O_Enode (To_Int32 (Val)), O_Enode_Null);
end New_Const_U32;
Last_Decl : O_Dnode := 2;
Cur_Block : O_Enode := O_Enode_Null;
procedure Start_Declare_Stmt
is
Res : O_Enode;
begin
New_Enode_Stmt (OE_Beg, Cur_Block, O_Enode_Null);
Res := Enodes.Last;
Enodes.Table (Res).Arg2 := O_Enode
(Ortho_Code.Decls.Start_Declare_Stmt);
Cur_Block := Res;
end Start_Declare_Stmt;
function New_Stack (Rtype : O_Tnode) return O_Enode is
begin
return New_Enode (OE_Get_Stack, Rtype, O_Enode_Null, O_Enode_Null);
end New_Stack;
procedure New_Stack_Restore (Blk : O_Enode)
is
Save_Asgn : O_Enode;
Save_Var : O_Dnode;
begin
Save_Asgn := Get_Stmt_Link (Blk);
Save_Var := Get_Addr_Object (Get_Assign_Target (Save_Asgn));
New_Enode_Stmt (OE_Set_Stack, New_Value (New_Obj (Save_Var)),
O_Enode_Null);
end New_Stack_Restore;
procedure Finish_Declare_Stmt
is
Parent : O_Dnode;
begin
if Get_Block_Has_Alloca (Cur_Block) then
New_Stack_Restore (Cur_Block);
end if;
New_Enode_Stmt (OE_End, Cur_Block, O_Enode_Null);
Cur_Block := Get_Block_Parent (Cur_Block);
if Cur_Block = O_Enode_Null then
Parent := O_Dnode_Null;
else
Parent := Get_Block_Decls (Cur_Block);
end if;
Ortho_Code.Decls.Finish_Declare_Stmt (Parent);
end Finish_Declare_Stmt;
function New_Label return O_Enode is
begin
return New_Enode (OE_Label, Mode_Nil, O_Tnode_Null,
Cur_Block, O_Enode_Null);
end New_Label;
procedure Start_Subprogram_Body (Func : O_Dnode)
is
Start : O_Enode;
D_Body : O_Dnode;
Data : Subprogram_Data_Acc;
begin
if Cur_Subprg = null then
Abi.Start_Body (Func);
end if;
Start := New_Enode (OE_Entry, Mode_Nil, O_Tnode_Null,
Last_Stmt, O_Enode_Null);
D_Body := Decls.Start_Subprogram_Body (Func, Start);
-- Create the corresponding decl.
Enodes.Table (Start).Arg2 := O_Enode (D_Body);
-- Create the data record.
Data := new Subprogram_Data'(Parent => Cur_Subprg,
First_Child => null,
Last_Child => null,
Brother => null,
Depth => Get_Decl_Depth (Func),
D_Decl => Func,
E_Entry => Start,
D_Body => D_Body,
Exit_Label => O_Enode_Null,
Last_Stmt => O_Enode_Null,
Stack_Max => 0,
Target => (others => <>));
if not Flag_Debug_Hli then
Data.Exit_Label := New_Label;
end if;
-- Link the record.
if Cur_Subprg = null then
-- A top-level subprogram.
if First_Subprg = null then
First_Subprg := Data;
else
Last_Subprg.Brother := Data;
end if;
Last_Subprg := Data;
else
-- A nested subprogram.
if Cur_Subprg.First_Child = null then
Cur_Subprg.First_Child := Data;
else
Cur_Subprg.Last_Child.Brother := Data;
end if;
Cur_Subprg.Last_Child := Data;
-- Also save last_stmt.
Cur_Subprg.Last_Stmt := Last_Stmt;
end if;
Cur_Subprg := Data;
Last_Stmt := Start;
Start_Declare_Stmt;
-- Create a basic block for the beginning of the subprogram.
Start_BB;
-- Disp declarations.
if Cur_Subprg.Parent = null then
if Ortho_Code.Debug.Flag_Debug_Code then
while Last_Decl <= D_Body loop
case Get_Decl_Kind (Last_Decl) is
when OD_Block =>
-- Skip blocks.
Disp_Decl (1, Last_Decl);
Last_Decl := Get_Block_Last (Last_Decl) + 1;
when others =>
Disp_Decl (1, Last_Decl);
Last_Decl := Last_Decl + 1;
end case;
end loop;
end if;
end if;
end Start_Subprogram_Body;
procedure Finish_Subprogram_Body
is
Parent : Subprogram_Data_Acc;
begin
Finish_Declare_Stmt;
-- Create a new basic block for the epilog.
Start_BB;
if not Flag_Debug_Hli then
Link_Stmt (Cur_Subprg.Exit_Label);
end if;
New_Enode_Stmt (OE_Leave, O_Enode_Null, O_Enode_Null);
-- Save last statement.
Cur_Subprg.Last_Stmt := Enodes.Last;
-- Set Leave of Entry.
Set_Entry_Leave (Cur_Subprg.E_Entry, Enodes.Last);
Decls.Finish_Subprogram_Body;
Parent := Cur_Subprg.Parent;
if Flags.Flag_Optimize then
Opts.Optimize_Subprg (Cur_Subprg);
end if;
if Parent = null then
-- This is a top-level subprogram.
if Ortho_Code.Debug.Flag_Disp_Code then
Disps.Disp_Subprg (Cur_Subprg);
end if;
if Ortho_Code.Debug.Flag_Dump_Code then
Disp_Subprg_Body (1, Cur_Subprg.E_Entry);
end if;
if not Ortho_Code.Debug.Flag_Debug_Dump then
Abi.Finish_Body;
end if;
end if;
-- Restore Cur_Subprg.
Cur_Subprg := Parent;
-- Restore Last_Stmt.
if Cur_Subprg = null then
Last_Stmt := O_Enode_Null;
else
Last_Stmt := Cur_Subprg.Last_Stmt;
end if;
end Finish_Subprogram_Body;
function Get_Inner_Alloca (Label : O_Enode) return O_Enode
is
Res : O_Enode := O_Enode_Null;
Blk : O_Enode;
Last_Blk : constant O_Enode := Get_Label_Block (Label);
begin
Blk := Cur_Block;
while Blk /= Last_Blk loop
if Get_Block_Has_Alloca (Blk) then
Res := Blk;
end if;
Blk := Get_Block_Parent (Blk);
end loop;
return Res;
end Get_Inner_Alloca;
procedure Emit_Jmp (Code : OE_Kind; Expr : O_Enode; Label : O_Enode)
is
begin
-- Discard jump after jump.
if Code /= OE_Jump or else Get_Expr_Kind (Last_Stmt) /= OE_Jump then
New_Enode_Stmt (Code, Expr, Label);
end if;
end Emit_Jmp;
-- If there is stack allocated memory to be freed, free it.
-- Then jump to LABEL.
procedure New_Allocb_Jump (Label : O_Enode)
is
Inner_Alloca : O_Enode;
begin
Inner_Alloca := Get_Inner_Alloca (Label);
if Inner_Alloca /= O_Enode_Null then
New_Stack_Restore (Inner_Alloca);
end if;
Emit_Jmp (OE_Jump, O_Enode_Null, Label);
end New_Allocb_Jump;
function New_Lit (Lit : O_Cnode) return O_Enode
is
L_Type : O_Tnode;
H, L : Uns32;
begin
L_Type := Get_Const_Type (Lit);
if Flag_Debug_Hli then
return New_Enode (OE_Lit, L_Type, O_Enode (Lit), O_Enode_Null);
else
case Get_Const_Kind (Lit) is
when OC_Signed
| OC_Unsigned
| OC_Float
| OC_Null
| OC_Lit =>
Get_Const_Bytes (Lit, H, L);
return New_Enode
(OE_Const, L_Type,
O_Enode (To_Int32 (L)), O_Enode (To_Int32 (H)));
when OC_Address
| OC_Subprg_Address =>
return New_Enode (OE_Addrg, L_Type,
O_Enode (Get_Const_Decl (Lit)), O_Enode_Null);
when OC_Array
| OC_Record
| OC_Union
| OC_Sizeof
| OC_Alignof =>
raise Syntax_Error;
end case;
end if;
end New_Lit;
function Is_Expr_S32 (Cst : O_Enode) return Boolean is
begin
pragma Assert (Get_Expr_Kind (Cst) = OE_Const);
return Shift_Right_Arithmetic (Get_Expr_Low (Cst), 32)
= Get_Expr_High (Cst);
end Is_Expr_S32;
function Get_Static_Chain (Depth : O_Depth) return O_Enode
is
Cur_Depth : O_Depth := Cur_Subprg.Depth;
Subprg : Subprogram_Data_Acc;
Res : O_Enode;
begin
if Depth = Cur_Depth then
return New_Enode (OE_Get_Frame, Abi.Mode_Ptr, O_Tnode_Ptr,
O_Enode_Null, O_Enode_Null);
else
Subprg := Cur_Subprg;
Res := O_Enode_Null;
loop
-- The static chain is the first interface of the subprogram.
Res := New_Enode (OE_Addrl, Abi.Mode_Ptr, O_Tnode_Ptr,
O_Enode (Get_Subprg_Interfaces (Subprg.D_Decl)),
Res);
Res := New_Enode (OE_Indir, O_Tnode_Ptr, Res, O_Enode_Null);
Cur_Depth := Cur_Depth - 1;
if Cur_Depth = Depth then
return Res;
end if;
Subprg := Subprg.Parent;
end loop;
end if;
end Get_Static_Chain;
function New_Obj (Obj : O_Dnode) return O_Lnode
is
O_Type : O_Tnode;
Kind : OE_Kind;
Chain : O_Enode;
Depth : O_Depth;
begin
O_Type := Get_Decl_Type (Obj);
case Get_Decl_Kind (Obj) is
when OD_Local
| OD_Interface =>
Kind := OE_Addrl;
-- Local declarations are 1 deeper than their subprogram.
Depth := Get_Decl_Depth (Obj) - 1;
if Depth /= Cur_Subprg.Depth then
Chain := Get_Static_Chain (Depth);
else
Chain := O_Enode_Null;
end if;
when OD_Var
| OD_Const =>
Kind := OE_Addrg;
Chain := O_Enode_Null;
when others =>
raise Program_Error;
end case;
return O_Lnode (New_Enode (Kind, Abi.Mode_Ptr, O_Type,
O_Enode (Obj), Chain));
end New_Obj;
function New_Dyadic_Op (Kind : ON_Dyadic_Op_Kind; Left, Right : O_Enode)
return O_Enode
is
L_Type : O_Tnode;
begin
L_Type := Get_Enode_Type (Left);
if Flag_Debug_Assert then
if L_Type /= Get_Enode_Type (Right) then
raise Syntax_Error;
end if;
if Get_Type_Mode (L_Type) = Mode_Blk then
raise Syntax_Error;
end if;
Check_Ref (Left);
Check_Ref (Right);
end if;
return New_Enode (OE_Kind'Val (ON_Op_Kind'Pos (Kind)),
L_Type, Left, Right);
end New_Dyadic_Op;
function New_Monadic_Op (Kind : ON_Monadic_Op_Kind; Operand : O_Enode)
return O_Enode
is
O_Type : O_Tnode;
begin
O_Type := Get_Enode_Type (Operand);
if Flag_Debug_Assert then
if Get_Type_Mode (O_Type) = Mode_Blk then
raise Syntax_Error;
end if;
Check_Ref (Operand);
end if;
return New_Enode (OE_Kind'Val (ON_Op_Kind'Pos (Kind)), O_Type,
Operand, O_Enode_Null);
end New_Monadic_Op;
function New_Compare_Op
(Kind : ON_Compare_Op_Kind; Left, Right : O_Enode; Ntype : O_Tnode)
return O_Enode
is
Res : O_Enode;
begin
if Flag_Debug_Assert then
if Get_Enode_Type (Left) /= Get_Enode_Type (Right) then
raise Syntax_Error;
end if;
if Get_Expr_Mode (Left) = Mode_Blk then
raise Syntax_Error;
end if;
if Get_Type_Kind (Ntype) /= OT_Boolean then
raise Syntax_Error;
end if;
Check_Ref (Left);
Check_Ref (Right);
end if;
Res := New_Enode (OE_Kind'Val (ON_Op_Kind'Pos (Kind)), Ntype,
Left, Right);
if Flag_Debug_Hli then
return New_Enode (OE_Typed, Ntype, Res, O_Enode (Ntype));
else
return Res;
end if;
end New_Compare_Op;
function New_Sizeof (Atype : O_Tnode; Rtype : O_Tnode) return O_Enode is
begin
return New_Const_U32 (Get_Type_Size (Atype), Rtype);
end New_Sizeof;
function New_Offsetof (Field : O_Fnode; Rtype : O_Tnode) return O_Enode is
begin
return New_Const_U32 (Get_Field_Offset (Field), Rtype);
end New_Offsetof;
function Is_Pow2 (V : Uns32) return Boolean is
begin
return (V and -V) = V;
end Is_Pow2;
function Extract_Pow2 (V : Uns32) return Uns32 is
begin
for I in Natural range 0 .. 31 loop
if V = Shift_Left (1, I) then
return Uns32 (I);
end if;
end loop;
raise Program_Error;
end Extract_Pow2;
function New_Index_Slice_Element
(Arr : O_Lnode; Index : O_Enode; Res_Type : O_Tnode)
return O_Lnode
is
El_Type : O_Tnode;
In_Type : O_Tnode;
Sz : O_Enode;
El_Size : Uns32;
begin
El_Type := Get_Type_Array_Element (Get_Enode_Type (O_Enode (Arr)));
In_Type := Get_Enode_Type (Index);
if Flag_Debug_Assert then
Check_Ref (Index);
Check_Ref (Arr);
end if;
-- result := arr + index * sizeof (element).
El_Size := Get_Type_Size (El_Type);
if El_Size = 1 then
Sz := Index;
elsif Get_Expr_Kind (Index) = OE_Const then
-- FIXME: may recycle previous index?
Sz := New_Const_U32 (Get_Expr_Low (Index) * El_Size, In_Type);
else
if Is_Pow2 (El_Size) then
Sz := New_Const_U32 (Extract_Pow2 (El_Size), In_Type);
Sz := New_Enode (OE_Shl, In_Type, Index, Sz);
else
Sz := New_Const_U32 (El_Size, In_Type);
Sz := New_Enode (OE_Mul, In_Type, Index, Sz);
end if;
end if;
return O_Lnode (New_Enode (OE_Add, Abi.Mode_Ptr, Res_Type,
O_Enode (Arr), Sz));
end New_Index_Slice_Element;
function New_Hli_Index_Slice
(Kind : OE_Kind; Res_Type : O_Tnode; Arr : O_Lnode; Index : O_Enode)
return O_Lnode
is
begin
if Flag_Debug_Assert then
Check_Ref (Index);
Check_Ref (Arr);
end if;
return O_Lnode (New_Enode (Kind, Res_Type, O_Enode (Arr), Index));
end New_Hli_Index_Slice;
-- Get an element of an array.
-- INDEX must be of the type of the array index.
function New_Indexed_Element (Arr : O_Lnode; Index : O_Enode)
return O_Lnode
is
El_Type : O_Tnode;
begin
El_Type := Get_Type_Array_Element (Get_Enode_Type (O_Enode (Arr)));
if Flag_Debug_Hli then
return New_Hli_Index_Slice (OE_Index_Ref, El_Type, Arr, Index);
else
return New_Index_Slice_Element (Arr, Index, El_Type);
end if;
end New_Indexed_Element;
-- Get a slice of an array; this is equivalent to a conversion between
-- an array or an array subtype and an array subtype.
-- RES_TYPE must be an array_sub_type whose base type is the same as the
-- base type of ARR.
-- INDEX must be of the type of the array index.
function New_Slice (Arr : O_Lnode; Res_Type : O_Tnode; Index : O_Enode)
return O_Lnode
is
begin
if Flag_Debug_Hli then
return New_Hli_Index_Slice (OE_Slice_Ref, Res_Type, Arr, Index);
else
return New_Index_Slice_Element (Arr, Index, Res_Type);
end if;
end New_Slice;
function New_Selected_Element (Rec : O_Lnode; El : O_Fnode)
return O_Lnode
is
Offset : Uns32;
Off : O_Enode;
Res_Type : O_Tnode;
begin
if Flag_Debug_Assert then
Check_Ref (Rec);
end if;
Res_Type := Get_Field_Type (El);
if Flag_Debug_Hli then
return O_Lnode (New_Enode (OE_Record_Ref, Res_Type,
O_Enode (Rec), O_Enode (El)));
else
Offset := Get_Field_Offset (El);
if Offset = 0 then
return O_Lnode (New_Enode (OE_Conv_Ptr, Abi.Mode_Ptr, Res_Type,
O_Enode (Rec), O_Enode (Res_Type)));
else
Off := New_Enode (OE_Const, Mode_U32, O_Tnode_Null,
O_Enode (Offset), O_Enode_Null);
return O_Lnode (New_Enode (OE_Add, Abi.Mode_Ptr, Res_Type,
O_Enode (Rec), Off));
end if;
end if;
end New_Selected_Element;
function New_Access_Element (Acc : O_Enode) return O_Lnode
is
Acc_Type : O_Tnode;
Res_Type : O_Tnode;
begin
Acc_Type := Get_Enode_Type (Acc);
if Flag_Debug_Assert then
if Get_Type_Kind (Acc_Type) /= OT_Access then
raise Syntax_Error;
end if;
Check_Ref (Acc);
end if;
Res_Type := Get_Type_Access_Type (Acc_Type);
if Flag_Debug_Hli then
return O_Lnode (New_Enode (OE_Access_Ref, Abi.Mode_Ptr, Res_Type,
Acc, O_Enode_Null));
else
return O_Lnode (New_Enode (OE_Conv_Ptr, Abi.Mode_Ptr, Res_Type,
Acc, O_Enode (Res_Type)));
end if;
end New_Access_Element;
function New_Convert_Ov (Val : O_Enode; Rtype : O_Tnode) return O_Enode is
begin
if Flag_Debug_Assert then
Check_Ref (Val);
end if;
return New_Enode (OE_Conv, Rtype, Val, O_Enode (Rtype));
end New_Convert_Ov;
function New_Unchecked_Address (Lvalue : O_Lnode; Atype : O_Tnode)
return O_Enode is
begin
if Flag_Debug_Assert then
if Get_Type_Kind (Atype) /= OT_Access then
raise Syntax_Error;
end if;
Check_Ref (Lvalue);
end if;
return New_Enode (OE_Conv_Ptr, Abi.Mode_Ptr, Atype,
O_Enode (Lvalue), O_Enode (Atype));
end New_Unchecked_Address;
function New_Address (Lvalue : O_Lnode; Atype : O_Tnode) return O_Enode is
begin
if Flag_Debug_Assert then
if Get_Type_Kind (Atype) /= OT_Access then
raise Syntax_Error;
end if;
if Get_Base_Type (Get_Enode_Type (O_Enode (Lvalue)))
/= Get_Base_Type (Get_Type_Access_Type (Atype))
then
raise Syntax_Error;
end if;
Check_Ref (Lvalue);
end if;
return New_Enode (OE_Conv_Ptr, Abi.Mode_Ptr, Atype,
O_Enode (Lvalue), O_Enode (Atype));
end New_Address;
function New_Subprogram_Address (Subprg : O_Dnode; Atype : O_Tnode)
return O_Enode is
begin
raise Program_Error;
return O_Enode_Null;
end New_Subprogram_Address;
function New_Value (Lvalue : O_Lnode) return O_Enode
is
V_Type : O_Tnode;
begin
V_Type := Get_Enode_Type (O_Enode (Lvalue));
if Flag_Debug_Assert then
Check_Ref (Lvalue);
end if;
return New_Enode (OE_Indir, V_Type, O_Enode (Lvalue), O_Enode_Null);
end New_Value;
function New_Alloca (Rtype : O_Tnode; Size : O_Enode) return O_Enode
is
Save_Var : O_Dnode;
Stmt : O_Enode;
St_Type : O_Tnode;
begin
if Flag_Debug_Assert then
Check_Ref (Size);
if Get_Type_Kind (Rtype) /= OT_Access then
raise Syntax_Error;
end if;
if Get_Type_Kind (Get_Enode_Type (Size)) /= OT_Unsigned then
raise Syntax_Error;
end if;
end if;
if not Get_Block_Has_Alloca (Cur_Block) then
Set_Block_Has_Alloca (Cur_Block, True);
if Stack_Ptr_Type /= O_Tnode_Null then
St_Type := Stack_Ptr_Type;
else
St_Type := Rtype;
end if;
-- Add a decl.
New_Var_Decl (Save_Var, O_Ident_Nul, O_Storage_Local, St_Type);
-- Add insn to save stack ptr.
Stmt := New_Enode (OE_Asgn, St_Type,
New_Stack (St_Type),
O_Enode (New_Obj (Save_Var)));
if Cur_Block = Last_Stmt then
Set_Stmt_Link (Last_Stmt, Stmt);
Last_Stmt := Stmt;
else
Set_Stmt_Link (Stmt, Get_Stmt_Link (Cur_Block));
Set_Stmt_Link (Cur_Block, Stmt);
end if;
end if;
return New_Enode (OE_Alloca, Rtype, Size, O_Enode (Rtype));
end New_Alloca;
procedure Start_Association (Assocs : out O_Assoc_List; Subprg : O_Dnode)
is
Depth : O_Depth;
Arg : O_Enode;
First_Inter : O_Dnode;
begin
First_Inter := Get_Subprg_Interfaces (Subprg);
if Get_Decl_Storage (Subprg) = O_Storage_Local then
Depth := Get_Decl_Depth (Subprg);
Arg := New_Enode (OE_Arg, Abi.Mode_Ptr, O_Tnode_Ptr,
Get_Static_Chain (Depth - 1), O_Enode_Null);
First_Inter := Get_Interface_Chain (First_Inter);
else
Arg := O_Enode_Null;
end if;
Assocs := (Subprg => Subprg,
First_Arg => Arg,
Last_Arg => Arg,
Next_Inter => First_Inter);
end Start_Association;
procedure New_Association (Assocs : in out O_Assoc_List; Val : O_Enode)
is
V_Type : O_Tnode;
Mode : Mode_Type;
N_Mode : Mode_Type;
Res : O_Enode;
begin
V_Type := Get_Enode_Type (Val);
if Flag_Debug_Assert then
if Assocs.Next_Inter = O_Dnode_Null then
-- More assocs than interfaces.
raise Syntax_Error;
end if;
Check_Value_Type (Val, Get_Decl_Type (Assocs.Next_Inter));
Check_Ref (Val);
end if;
-- Follow the C convention call: no parameters shorter than int.
Mode := Get_Type_Mode (V_Type);
case Mode is
when Mode_B2
| Mode_U8
| Mode_U16 =>
N_Mode := Mode_U32;
when Mode_I8
| Mode_I16 =>
N_Mode := Mode_I32;
when Mode_P32
| Mode_U32
| Mode_I32
| Mode_U64
| Mode_I64
| Mode_P64
| Mode_F32
| Mode_F64 =>
N_Mode := Mode;
when Mode_Blk
| Mode_Nil
| Mode_X1 =>
raise Program_Error;
end case;
if N_Mode /= Mode and not Flag_Debug_Hli then
Res := New_Enode (OE_Conv, N_Mode, V_Type, Val, O_Enode (V_Type));
else
Res := Val;
end if;
Res := New_Enode (OE_Arg, N_Mode, V_Type, Res, O_Enode_Null);
if Assocs.Last_Arg /= O_Enode_Null then
Enodes.Table (Assocs.Last_Arg).Arg2 := Res;
else
Assocs.First_Arg := Res;
end if;
Assocs.Last_Arg := Res;
Assocs.Next_Inter := Get_Interface_Chain (Assocs.Next_Inter);
end New_Association;
function New_Function_Call (Assocs : O_Assoc_List) return O_Enode
is
F_Type : O_Tnode;
begin
if Flag_Debug_Assert then
if Assocs.Next_Inter /= O_Dnode_Null then
-- Not enough assocs.
raise Syntax_Error;
end if;
end if;
F_Type := Get_Decl_Type (Assocs.Subprg);
return New_Enode (OE_Call, F_Type,
O_Enode (Assocs.Subprg), Assocs.First_Arg);
end New_Function_Call;
procedure New_Procedure_Call (Assocs : in out O_Assoc_List) is
begin
if Flag_Debug_Assert then
if Assocs.Next_Inter /= O_Dnode_Null then
-- Not enough assocs.
raise Syntax_Error;
end if;
end if;
New_Enode_Stmt (OE_Call, O_Enode (Assocs.Subprg), Assocs.First_Arg);
end New_Procedure_Call;
procedure New_Assign_Stmt (Target : O_Lnode; Value : O_Enode)
is
V_Type : O_Tnode;
begin
V_Type := Get_Enode_Type (Value);
if Flag_Debug_Assert then
Check_Value_Type (Value, Get_Enode_Type (O_Enode (Target)));
Check_Ref (Value);
Check_Ref (Target);
end if;
New_Enode_Stmt (OE_Asgn, Get_Type_Mode (V_Type),
Value, O_Enode (Target));
end New_Assign_Stmt;
procedure New_Return_Stmt (Value : O_Enode)
is
V_Type : O_Tnode;
begin
V_Type := Get_Enode_Type (Value);
if Flag_Debug_Assert then
Check_Ref (Value);
Check_Value_Type (Value, Get_Decl_Type (Cur_Subprg.D_Decl));
end if;
New_Enode_Stmt (OE_Ret, Get_Type_Mode (V_Type), Value, O_Enode_Null);
if not Flag_Debug_Hli then
New_Allocb_Jump (Cur_Subprg.Exit_Label);
end if;
end New_Return_Stmt;
procedure New_Return_Stmt is
begin
if Flag_Debug_Assert then
if Get_Decl_Kind (Cur_Subprg.D_Decl) /= OD_Procedure then
raise Syntax_Error;
end if;
end if;
if not Flag_Debug_Hli then
New_Allocb_Jump (Cur_Subprg.Exit_Label);
else
New_Enode_Stmt (OE_Ret, Mode_Nil, O_Enode_Null, O_Enode_Null);
end if;
end New_Return_Stmt;
procedure Start_If_Stmt (Block : out O_If_Block; Cond : O_Enode) is
begin
if Flag_Debug_Assert then
if Get_Expr_Mode (Cond) /= Mode_B2 then
-- COND must be a boolean.
raise Syntax_Error;
end if;
Check_Ref (Cond);
end if;
if not Flag_Lower_Stmt then
New_Enode_Stmt (OE_If, Cond, O_Enode_Null);
Block := (Label_End => O_Enode_Null,
Label_Next => Last_Stmt);
else
Block := (Label_End => O_Enode_Null,
Label_Next => New_Label);
Emit_Jmp (OE_Jump_F, Cond, Block.Label_Next);
Start_BB;
end if;
end Start_If_Stmt;
procedure New_Else_Stmt (Block : in out O_If_Block) is
begin
if not Flag_Lower_Stmt then
New_Enode_Stmt (OE_Else, O_Enode_Null, O_Enode_Null);
else
if Block.Label_End = O_Enode_Null then
Block.Label_End := New_Label;
end if;
Emit_Jmp (OE_Jump, O_Enode_Null, Block.Label_End);
Start_BB;
Link_Stmt (Block.Label_Next);
Block.Label_Next := O_Enode_Null;
end if;
end New_Else_Stmt;
procedure Finish_If_Stmt (Block : in out O_If_Block) is
begin
if not Flag_Lower_Stmt then
New_Enode_Stmt (OE_Endif, O_Enode_Null, O_Enode_Null);
else
-- Create a badic-block after the IF.
Start_BB;
if Block.Label_Next /= O_Enode_Null then
Link_Stmt (Block.Label_Next);
end if;
if Block.Label_End /= O_Enode_Null then
Link_Stmt (Block.Label_End);
end if;
end if;
end Finish_If_Stmt;
procedure Start_Loop_Stmt (Label : out O_Snode) is
begin
if not Flag_Lower_Stmt then
New_Enode_Stmt (OE_Loop, O_Enode_Null, O_Enode_Null);
Label := (Label_Start => Last_Stmt,
Label_End => O_Enode_Null);
else
-- Create a basic-block at the beginning of the loop.
Start_BB;
Label.Label_Start := New_Label;
Link_Stmt (Label.Label_Start);
Label.Label_End := New_Label;
end if;
end Start_Loop_Stmt;
procedure Finish_Loop_Stmt (Label : in out O_Snode)
is
begin
if not Flag_Lower_Stmt then
New_Enode_Stmt (OE_Eloop, Label.Label_Start, O_Enode_Null);
else
Emit_Jmp (OE_Jump, O_Enode_Null, Label.Label_Start);
Start_BB;
Link_Stmt (Label.Label_End);
end if;
end Finish_Loop_Stmt;
procedure New_Exit_Stmt (L : O_Snode)
is
begin
if not Flag_Lower_Stmt then
New_Enode_Stmt (OE_Exit, O_Enode_Null, L.Label_Start);
else
New_Allocb_Jump (L.Label_End);
end if;
end New_Exit_Stmt;
procedure New_Next_Stmt (L : O_Snode)
is
begin
if not Flag_Lower_Stmt then
New_Enode_Stmt (OE_Next, O_Enode_Null, L.Label_Start);
else
New_Allocb_Jump (L.Label_Start);
end if;
end New_Next_Stmt;
procedure Start_Case_Stmt (Block : out O_Case_Block; Value : O_Enode)
is
V_Type : O_Tnode;
Mode : Mode_Type;
Start : O_Enode;
begin
V_Type := Get_Enode_Type (Value);
Mode := Get_Type_Mode (V_Type);
if Flag_Debug_Assert then
Check_Ref (Value);
case Mode is
when Mode_U8 .. Mode_U64
| Mode_I8 .. Mode_I64
| Mode_B2 =>
null;
when others =>
raise Syntax_Error;
end case;
end if;
New_Enode_Stmt (OE_Case, Mode, Value, O_Enode_Null);
Start := Enodes.Last;
if Flag_Debug_Hli then
Block := (Expr => Start,
Expr_Type => V_Type,
Last_Node => O_Enode_Null,
Label_End => O_Enode_Null,
Label_Branch => Start);
else
Block := (Expr => Start,
Expr_Type => V_Type,
Last_Node => Start,
Label_End => New_Label,
Label_Branch => O_Enode_Null);
end if;
end Start_Case_Stmt;
procedure Start_Choice (Block : in out O_Case_Block)
is
B : O_Enode;
begin
if Flag_Debug_Hli then
B := New_Enode (OE_Case_Branch, Mode_Nil, O_Tnode_Null,
O_Enode_Null, O_Enode_Null);
Link_Stmt (B);
-- Link it.
Set_Case_Branch (Block.Label_Branch, B);
Block.Label_Branch := B;
else
-- Jump to the end of the case statement.
-- If there is already a branch open, this is ok
-- (do not fall-through).
-- If there is no branch open, then this is the default choice
-- (nothing to do).
Emit_Jmp (OE_Jump, O_Enode_Null, Block.Label_End);
-- Create a label for the code of this branch.
Block.Label_Branch := New_Label;
end if;
end Start_Choice;
procedure Insert_Choice_Stmt (Block : in out O_Case_Block; Stmt : O_Enode)
is
Prev : O_Enode;
begin
Prev := Get_Stmt_Link (Block.Last_Node);
Set_Stmt_Link (Block.Last_Node, Stmt);
Block.Last_Node := Stmt;
if Prev = O_Enode_Null then
Last_Stmt := Stmt;
else
Set_Stmt_Link (Stmt, Prev);
end if;
end Insert_Choice_Stmt;
procedure Emit_Choice_Jmp (Block : in out O_Case_Block;
Code : OE_Kind; Expr : O_Enode; Label : O_Enode)
is
Jmp : O_Enode;
begin
Jmp := New_Enode (Code, Mode_Nil, O_Tnode_Null, Expr, Label);
Insert_Choice_Stmt (Block, Jmp);
end Emit_Choice_Jmp;
-- Create a node containing the value of the case expression.
function New_Case_Expr (Block : O_Case_Block) return O_Enode is
begin
return New_Enode (OE_Case_Expr, Block.Expr_Type,
Block.Expr, O_Enode_Null);
end New_Case_Expr;
procedure New_Hli_Choice (Block : in out O_Case_Block;
Hi, Lo : O_Enode)
is
Res : O_Enode;
begin
Res := New_Enode (OE_Case_Choice, Mode_Nil, O_Tnode_Null, Hi, Lo);
if Block.Label_End = O_Enode_Null then
Set_Case_Branch_Choice (Block.Label_Branch, Res);
else
Set_Case_Choice_Link (Block.Label_End, Res);
end if;
Block.Label_End := Res;
end New_Hli_Choice;
procedure New_Expr_Choice (Block : in out O_Case_Block; Expr : O_Cnode)
is
Res : O_Enode;
begin
if Flag_Debug_Hli then
New_Hli_Choice (Block, New_Lit (Expr), O_Enode_Null);
else
Res := New_Enode (OE_Eq, Mode_B2, O_Tnode_Null,
New_Case_Expr (Block), New_Lit (Expr));
Emit_Choice_Jmp (Block, OE_Jump_T, Res, Block.Label_Branch);
end if;
end New_Expr_Choice;
procedure New_Range_Choice (Block : in out O_Case_Block;
Low, High : O_Cnode)
is
E1 : O_Enode;
E2 : O_Enode;
Label : O_Enode;
begin
if Flag_Debug_Hli then
New_Hli_Choice (Block, New_Lit (Low), New_Lit (High));
else
-- Internal label.
Label := New_Label;
E1 := New_Enode (OE_Lt, Mode_B2, O_Tnode_Null,
New_Case_Expr (Block), New_Lit (Low));
Emit_Choice_Jmp (Block, OE_Jump_T, E1, Label);
E2 := New_Enode (OE_Le, Mode_B2, O_Tnode_Null,
New_Case_Expr (Block), New_Lit (High));
Emit_Choice_Jmp (Block, OE_Jump_T, E2, Block.Label_Branch);
Insert_Choice_Stmt (Block, Label);
end if;
end New_Range_Choice;
procedure New_Default_Choice (Block : in out O_Case_Block) is
begin
if Flag_Debug_Hli then
New_Hli_Choice (Block, O_Enode_Null, O_Enode_Null);
else
-- Jump to the code.
Emit_Choice_Jmp (Block, OE_Jump, O_Enode_Null, Block.Label_Branch);
end if;
end New_Default_Choice;
procedure Finish_Choice (Block : in out O_Case_Block) is
begin
if Flag_Debug_Hli then
Block.Label_End := O_Enode_Null;
else
-- Put the label of the branch.
Start_BB;
Link_Stmt (Block.Label_Branch);
end if;
end Finish_Choice;
procedure Finish_Case_Stmt (Block : in out O_Case_Block) is
begin
if Flag_Debug_Hli then
New_Enode_Stmt (OE_Case_End, O_Enode_Null, O_Enode_Null);
else
-- Jump to the end of the case statement.
-- Note: this is not required, since the next instruction is the
-- label.
-- Emit_Jmp (OE_Jump, O_Enode_Null, Block.Label_End);
-- Put the label of the end of the case.
Start_BB;
Link_Stmt (Block.Label_End);
Block.Label_End := O_Enode_Null;
end if;
end Finish_Case_Stmt;
procedure New_Debug_Line_Stmt (Line : Natural) is
begin
New_Enode_Stmt (OE_Line, O_Enode (Line), O_Enode_Null);
end New_Debug_Line_Stmt;
procedure Debug_Expr (N : O_Enode)
is
use Ada.Text_IO;
use Ortho_Code.Debug.Int32_IO;
Indent : constant Count := Col;
begin
Put (Int32 (N), 0);
Set_Col (Indent + 7);
Disp_Mode (Get_Expr_Mode (N));
Put (" ");
Put (OE_Kind'Image (Get_Expr_Kind (N)));
Set_Col (Indent + 28);
-- Put (Abi.Image_Insn (Get_Expr_Insn (N)));
-- Put (" ");
Put (Abi.Image_Reg (Get_Expr_Reg (N)));
Put (" ");
Put (Int32 (Enodes.Table (N).Arg1), 7);
Put (Int32 (Enodes.Table (N).Arg2), 7);
Put (Enodes.Table (N).Info, 7);
New_Line;
end Debug_Expr;
procedure Disp_Subprg_Body (Indent : Natural; Subprg : O_Enode)
is
use Ada.Text_IO;
N : O_Enode;
N_Indent : Natural;
begin
N := Subprg;
if Get_Expr_Kind (N) /= OE_Entry then
raise Program_Error;
end if;
-- Display the entry.
Set_Col (Count (Indent));
Debug_Expr (N);
-- Display the subprogram, binding.
N_Indent := Indent;-- + 1;
N := N + 1;
loop
case Get_Expr_Kind (N) is
when OE_Entry =>
N := Get_Entry_Leave (N) + 1;
when OE_Leave =>
Set_Col (Count (Indent));
Debug_Expr (N);
exit;
when others =>
Set_Col (Count (N_Indent));
Debug_Expr (N);
case Get_Expr_Kind (N) is
when OE_Beg =>
Disp_Block (N_Indent + 2,
O_Dnode (Enodes.Table (N).Arg2));
N_Indent := N_Indent + 1;
when OE_End =>
N_Indent := N_Indent - 1;
when others =>
null;
end case;
N := N + 1;
end case;
end loop;
end Disp_Subprg_Body;
procedure Disp_All_Enode is
begin
for I in Enodes.First .. Enodes.Last loop
Debug_Expr (I);
end loop;
end Disp_All_Enode;
Max_Enode : O_Enode := O_Enode_Null;
procedure Mark (M : out Mark_Type) is
begin
M.Enode := Enodes.Last;
end Mark;
procedure Release (M : Mark_Type) is
begin
Max_Enode := O_Enode'Max (Max_Enode, Enodes.Last);
Enodes.Set_Last (M.Enode);
end Release;
procedure Disp_Stats
is
use Ada.Text_IO;
begin
Max_Enode := O_Enode'Max (Max_Enode, Enodes.Last);
Put ("Number of Enodes:" & O_Enode'Image (Enodes.Last));
Put (", max:" & O_Enode'Image (Max_Enode));
New_Line;
end Disp_Stats;
procedure Free_Subprogram_Data (Data : in out Subprogram_Data_Acc)
is
procedure Free is new Ada.Unchecked_Deallocation
(Subprogram_Data, Subprogram_Data_Acc);
Ch, N_Ch : Subprogram_Data_Acc;
begin
Ch := Data.First_Child;
while Ch /= null loop
N_Ch := Ch.Brother;
Free_Subprogram_Data (Ch);
Ch := N_Ch;
end loop;
Free (Data);
end Free_Subprogram_Data;
procedure Finish is
begin
Enodes.Free;
Free_Subprogram_Data (First_Subprg);
end Finish;
end Ortho_Code.Exprs;
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