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|
-- numeric_std
-- Copyright (C) 2019 Tristan Gingold
--
-- This file is part of GHDL.
--
-- 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 Types_Utils; use Types_Utils;
with Elab.Memtype; use Elab.Memtype;
with Synth.Errors; use Synth.Errors;
with Synth.Ieee.Utils; use Synth.Ieee.Utils;
with Synth.Source; use Synth.Source;
package body Synth.Ieee.Numeric_Std is
function Create_Res_Type (Otyp : Type_Acc; Len : Uns32) return Type_Acc is
begin
if Otyp.Abound.Len = Len
and then Otyp.Abound.Right = 0
and then Otyp.Abound.Dir = Dir_Downto
and then not Otyp.Is_Global
then
-- Try to reuse the same type as the parameter.
-- But the result type must be allocated on the expr_pool.
-- FIXME: is this code ever executed ?
pragma Assert (Otyp.Abound.Left = Int32 (Len) - 1);
return Otyp;
end if;
return Create_Vec_Type_By_Length (Len, Otyp.Arr_El);
end Create_Res_Type;
procedure Fill (Res : Memtyp; V : Std_Ulogic) is
begin
for I in 1 .. Res.Typ.Abound.Len loop
Write_Std_Logic (Res.Mem, I - 1, V);
end loop;
end Fill;
-- Return 'X' if V has at least one 'X',
-- Return '1' if V has at least one '1' but no 'X'.
-- Otherwise return '0' if V is 0.
function Has_0x (V : Memtyp) return Sl_X01
is
Res : Sl_X01 := '0';
E : Sl_X01;
begin
for I in 0 .. V.Typ.Abound.Len - 1 loop
E := To_X01 (Read_Std_Logic (V.Mem, I));
if E = 'X' then
return 'X';
elsif E = '1' then
Res := '1';
end if;
end loop;
return Res;
end Has_0x;
procedure Warn_Compare_Null (Loc : Location_Type) is
begin
Warning_Msg_Synth (Loc, "null argument detected, returning false");
end Warn_Compare_Null;
procedure Warn_Compare_Meta (Loc : Location_Type) is
begin
Warning_Msg_Synth (Loc, "metavalue detected, returning false");
end Warn_Compare_Meta;
function Compare_Uns_Uns (Left, Right : Memtyp;
Err : Order_Type;
Loc : Location_Type) return Order_Type
is
Lw : constant Uns32 := Left.Typ.W;
Rw : constant Uns32 := Right.Typ.W;
Len : constant Uns32 := Uns32'Min (Left.Typ.W, Right.Typ.W);
L, R : Std_Ulogic;
begin
if Len = 0 then
Warn_Compare_Null (Loc);
return Err;
end if;
if Lw > Rw then
for I in 0 .. Lw - Rw - 1 loop
case To_X01 (Read_Std_Logic (Left.Mem, I)) is
when '0' =>
null;
when '1' =>
return Greater;
when 'X' =>
Warn_Compare_Meta (Loc);
return Err;
end case;
end loop;
elsif Lw < Rw then
for I in 0 .. Rw - Lw - 1 loop
case To_X01 (Read_Std_Logic (Right.Mem, I)) is
when '0' =>
null;
when '1' =>
return Less;
when 'X' =>
Warn_Compare_Meta (Loc);
return Err;
end case;
end loop;
end if;
for I in 0 .. Len - 1 loop
L := To_X01 (Read_Std_Logic (Left.Mem, Lw - Len + I));
R := To_X01 (Read_Std_Logic (Right.Mem, Rw - Len + I));
if L = 'X' or R = 'X' then
Warn_Compare_Meta (Loc);
return Err;
elsif L = '1' and R = '0' then
return Greater;
elsif L = '0' and R = '1' then
return Less;
end if;
end loop;
return Equal;
end Compare_Uns_Uns;
function Compare_Uns_Nat (Left, Right : Memtyp;
Err : Order_Type;
Loc : Location_Type) return Order_Type
is
Lw : constant Uns32 := Left.Typ.W;
Rval : constant Uns64 := To_Uns64 (Read_Discrete (Right));
L : Std_Ulogic;
Cnt : Uns32;
begin
if Lw = 0 then
Warn_Compare_Null (Loc);
return Err;
end if;
if Lw > 64 then
for I in 0 .. Lw - 64 - 1 loop
case To_X01 (Read_Std_Logic (Left.Mem, I)) is
when '0' =>
null;
when '1' =>
return Greater;
when 'X' =>
Warn_Compare_Meta (Loc);
return Err;
end case;
end loop;
Cnt := 64;
elsif Lw < 64 then
if Shift_Right (Rval, Natural (Lw)) /= 0 then
return Less;
end if;
Cnt := Lw;
else
Cnt := 64;
end if;
for I in reverse 0 .. Cnt - 1 loop
L := To_X01 (Read_Std_Logic (Left.Mem, Lw - I - 1));
if L = 'X' then
Warn_Compare_Meta (Loc);
return Err;
end if;
if (Shift_Right (Rval, Natural (I)) and 1) = 1 then
if L = '0' then
return Less;
end if;
else
if L = '1' then
return Greater;
end if;
end if;
end loop;
return Equal;
end Compare_Uns_Nat;
function Compare_Nat_Uns (Left, Right : Memtyp;
Err : Order_Type;
Loc : Location_Type) return Order_Type
is
Rw : constant Uns32 := Right.Typ.W;
Lval : constant Uns64 := To_Uns64 (Read_Discrete (Left));
R : Std_Ulogic;
Cnt : Uns32;
begin
if Rw = 0 then
Warn_Compare_Null (Loc);
return Err;
end if;
if Rw > 64 then
for I in 0 .. Rw - 64 - 1 loop
case To_X01 (Read_Std_Logic (Right.Mem, I)) is
when '0' =>
null;
when '1' =>
return Less;
when 'X' =>
Warn_Compare_Meta (Loc);
return Err;
end case;
end loop;
Cnt := 64;
elsif Rw < 64 then
if Shift_Right (Lval, Natural (Rw)) /= 0 then
return Greater;
end if;
Cnt := Rw;
else
Cnt := 64;
end if;
for I in reverse 0 .. Cnt - 1 loop
R := To_X01 (Read_Std_Logic (Right.Mem, Rw - I - 1));
if R = 'X' then
Warn_Compare_Meta (Loc);
return Err;
end if;
if (Shift_Right (Lval, Natural (I)) and 1) = 1 then
if R = '0' then
return Greater;
end if;
else
if R = '1' then
return Less;
end if;
end if;
end loop;
return Equal;
end Compare_Nat_Uns;
function Compare_Sgn_Sgn (Left, Right : Memtyp;
Err : Order_Type;
Loc : Location_Type) return Order_Type
is
Lw : constant Uns32 := Left.Typ.W;
Rw : constant Uns32 := Right.Typ.W;
Len : constant Uns32 := Uns32'Min (Lw, Rw);
P : Uns32;
L, R : Std_Ulogic;
Res : Order_Type;
begin
if Len = 0 then
Warn_Compare_Null (Loc);
return Err;
end if;
-- Compare the sign bit.
L := To_X01 (Read_Std_Logic (Left.Mem, 0));
R := To_X01 (Read_Std_Logic (Right.Mem, 0));
if L = '1' and R = '0' then
return Less;
elsif L = '0' and R = '1' then
return Greater;
else
Res := Equal;
end if;
-- Same sign.
for I in 0 .. Uns32'Max (Lw, Rw) - 1 loop
if I >= Lw then
P := Lw - 1;
else
P := I;
end if;
L := To_X01 (Read_Std_Logic (Left.Mem, Lw - 1 - P));
if I >= Rw then
P := Rw - 1;
else
P := I;
end if;
R := To_X01 (Read_Std_Logic (Right.Mem, Rw - 1 - P));
if L = 'X' or R = 'X' then
Warn_Compare_Meta (Loc);
return Err;
end if;
if L = '1' and R = '0' then
Res := Greater;
elsif L = '0' and R = '1' then
Res := Less;
end if;
end loop;
return Res;
end Compare_Sgn_Sgn;
function Compare_Sgn_Int (Left, Right : Memtyp;
Err : Order_Type;
Loc : Location_Type) return Order_Type
is
Lw : constant Uns32 := Left.Typ.W;
Rval : constant Int64 := Read_Discrete (Right);
Rd : Uns32;
R1 : Uns64;
Res : Order_Type;
L : Std_Ulogic;
begin
if Lw = 0 then
Warn_Compare_Null (Loc);
return Err;
end if;
Res := Equal;
R1 := To_Uns64 (Rval);
-- Same sign.
for I in 0 .. Lw - 1 loop
L := To_X01 (Read_Std_Logic (Left.Mem, Lw - 1 - I));
if L = 'X' then
Warn_Compare_Meta (Loc);
return Err;
end if;
Rd := Uns32 (R1 and 1);
R1 := Shift_Right_Arithmetic (R1, 1);
if L = '1' and then Rd = 0 then
Res := Greater;
elsif L = '0' and then Rd = 1 then
Res := Less;
end if;
end loop;
if L = '1' then
if Rval >= 0 then
Res := Less;
end if;
else
if Rval < 0 then
Res := Greater;
end if;
end if;
return Res;
end Compare_Sgn_Int;
function Add_Vec_Vec (L, R : Memtyp; Signed : Boolean; Loc : Location_Type)
return Memtyp
is
Llen : constant Uns32 := L.Typ.Abound.Len;
Rlen : constant Uns32 := R.Typ.Abound.Len;
Len : constant Uns32 := Uns32'Max (Llen, Rlen);
Res : Memtyp;
Lb, Rb, Carry : Sl_X01;
R_Ext, L_Ext : Sl_X01;
begin
if Rlen = 0 or Llen = 0 then
Res.Typ := Create_Res_Type (L.Typ, 0);
Res := Create_Memory (Res.Typ);
return Res;
end if;
Res.Typ := Create_Res_Type (L.Typ, Len);
Res := Create_Memory (Res.Typ);
if Signed then
-- Extend with the sign bit.
L_Ext := Sl_To_X01 (Read_Std_Logic (L.Mem, 0));
R_Ext := Sl_To_X01 (Read_Std_Logic (R.Mem, 0));
else
-- Extend with '0'.
L_Ext := '0';
R_Ext := '0';
end if;
Carry := '0';
for I in 1 .. Len loop
if I > Llen then
Lb := L_Ext;
else
Lb := Sl_To_X01 (Read_Std_Logic (L.Mem, Llen - I));
end if;
if I > Rlen then
Rb := R_Ext;
else
Rb := Sl_To_X01 (Read_Std_Logic (R.Mem, Rlen - I));
end if;
if Lb = 'X' or Rb = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""+"": non logical value detected");
Fill (Res, 'X');
exit;
end if;
Write_Std_Logic (Res.Mem, Len - I, Compute_Sum (Carry, Rb, Lb));
Carry := Compute_Carry (Carry, Rb, Lb);
end loop;
return Res;
end Add_Vec_Vec;
function Add_Uns_Uns (L, R : Memtyp; Loc : Location_Type) return Memtyp is
begin
return Add_Vec_Vec (L, R, False, Loc);
end Add_Uns_Uns;
function Log_To_Vec (Val : Memtyp; Vec : Memtyp) return Memtyp
is
Len : constant Uns32 := Vec.Typ.Abound.Len;
Res : Memtyp;
begin
if Len = 0 then
-- FIXME: is it an error ?
return Vec;
end if;
Res := Create_Memory (Vec.Typ);
Fill (Res, '0');
Write_U8 (Res.Mem + Size_Type (Len - 1), Read_U8 (Val.Mem));
return Res;
end Log_To_Vec;
function Add_Sgn_Sgn (L, R : Memtyp; Loc : Location_Type) return Memtyp is
begin
return Add_Vec_Vec (L, R, True, Loc);
end Add_Sgn_Sgn;
function Add_Vec_Int (L : Memtyp;
R : Uns64;
Signed : Boolean;
Loc : Location_Type) return Memtyp
is
Len : constant Uns32 := L.Typ.Abound.Len;
Res : Memtyp;
V : Uns64;
Lb, Rb, Carry : Sl_X01;
begin
Res.Typ := Create_Res_Type (L.Typ, Len);
Res := Create_Memory (Res.Typ);
if Len < 1 then
return Res;
end if;
V := R;
Carry := '0';
for I in 1 .. Len loop
Lb := Sl_To_X01 (Read_Std_Logic (L.Mem, Len - I));
Rb := Uns_To_01 (V and 1);
if Lb = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""+"": non logical value detected");
Fill (Res, 'X');
exit;
end if;
Write_Std_Logic (Res.Mem, Len - I, Compute_Sum (Carry, Rb, Lb));
Carry := Compute_Carry (Carry, Rb, Lb);
if Signed then
V := Shift_Right_Arithmetic (V, 1);
else
V := Shift_Right (V, 1);
end if;
end loop;
return Res;
end Add_Vec_Int;
function Add_Sgn_Int (L : Memtyp; R : Int64; Loc : Location_Type)
return Memtyp is
begin
return Add_Vec_Int (L, To_Uns64 (R), True, Loc);
end Add_Sgn_Int;
function Add_Uns_Nat (L : Memtyp; R : Uns64; Loc : Location_Type)
return Memtyp is
begin
return Add_Vec_Int (L, R, True, Loc);
end Add_Uns_Nat;
function Sub_Vec_Vec (L, R : Memtyp; Signed : Boolean; Loc : Location_Type)
return Memtyp
is
Llen : constant Uns32 := L.Typ.Abound.Len;
Rlen : constant Uns32 := R.Typ.Abound.Len;
Len : constant Uns32 := Uns32'Max (Llen, Rlen);
Res : Memtyp;
Lb, Rb, Carry : Sl_X01;
R_Ext, L_Ext : Sl_X01;
begin
if Llen = 0 or Rlen = 0 then
Res.Typ := Create_Res_Type (L.Typ, 0);
Res := Create_Memory (Res.Typ);
return Res;
end if;
Res.Typ := Create_Res_Type (L.Typ, Len);
Res := Create_Memory (Res.Typ);
if Signed then
-- Extend with the sign bit.
L_Ext := Sl_To_X01 (Read_Std_Logic (L.Mem, 0));
R_Ext := Sl_To_X01 (Read_Std_Logic (R.Mem, 0));
else
-- Extend with '0'.
L_Ext := '0';
R_Ext := '0';
end if;
Carry := '1';
for I in 1 .. Len loop
if I > Llen then
Lb := L_Ext;
else
Lb := Sl_To_X01 (Read_Std_Logic (L.Mem, Llen - I));
end if;
if I > Rlen then
Rb := R_Ext;
else
Rb := Sl_To_X01 (Read_Std_Logic (R.Mem, Rlen - I));
end if;
Rb := Not_Table (Rb);
if Lb = 'X' or Rb = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""-"": non logical value detected");
Fill (Res, 'X');
exit;
end if;
Write_Std_Logic (Res.Mem, Len - I, Compute_Sum (Carry, Rb, Lb));
Carry := Compute_Carry (Carry, Rb, Lb);
end loop;
return Res;
end Sub_Vec_Vec;
function Sub_Uns_Uns (L, R : Memtyp; Loc : Location_Type) return Memtyp is
begin
return Sub_Vec_Vec (L, R, False, Loc);
end Sub_Uns_Uns;
function Sub_Sgn_Sgn (L, R : Memtyp; Loc : Location_Type) return Memtyp is
begin
return Sub_Vec_Vec (L, R, True, Loc);
end Sub_Sgn_Sgn;
function Sub_Vec_Int (L : Memtyp;
R : Uns64;
Signed : Boolean;
Loc : Location_Type) return Memtyp
is
Len : constant Uns32 := L.Typ.Abound.Len;
Res : Memtyp;
V : Uns64;
Lb, Rb, Carry : Sl_X01;
begin
Res.Typ := Create_Res_Type (L.Typ, Len);
Res := Create_Memory (Res.Typ);
if Len < 1 then
return Res;
end if;
V := R;
Carry := '1';
for I in 1 .. Len loop
Lb := Sl_To_X01 (Read_Std_Logic (L.Mem, Len - I));
Rb := Uns_To_01 (V and 1);
if Lb = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""+"": non logical value detected");
Fill (Res, 'X');
exit;
end if;
Rb := Not_Table (Rb);
Write_Std_Logic (Res.Mem, Len - I, Compute_Sum (Carry, Rb, Lb));
Carry := Compute_Carry (Carry, Rb, Lb);
if Signed then
V := Shift_Right_Arithmetic (V, 1);
else
V := Shift_Right (V, 1);
end if;
end loop;
return Res;
end Sub_Vec_Int;
function Sub_Sgn_Int (L : Memtyp;
R : Int64;
Loc : Location_Type) return Memtyp is
begin
return Sub_Vec_Int (L, To_Uns64 (R), True, Loc);
end Sub_Sgn_Int;
function Sub_Uns_Nat (L : Memtyp; R : Uns64; Loc : Location_Type)
return Memtyp is
begin
return Sub_Vec_Int (L, R, True, Loc);
end Sub_Uns_Nat;
function Sub_Int_Vec (L : Uns64;
R : Memtyp;
Signed : Boolean;
Loc : Location_Type) return Memtyp
is
Len : constant Uns32 := R.Typ.Abound.Len;
Res : Memtyp;
V : Uns64;
Lb, Rb, Carry : Sl_X01;
begin
Res.Typ := Create_Res_Type (R.Typ, Len);
Res := Create_Memory (Res.Typ);
if Len < 1 then
return Res;
end if;
V := L;
Carry := '1';
for I in 1 .. Len loop
Lb := Uns_To_01 (V and 1);
Rb := Sl_To_X01 (Read_Std_Logic (R.Mem, Len - I));
if Rb = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""+"": non logical value detected");
Fill (Res, 'X');
exit;
end if;
Rb := Not_Table (Rb);
Write_Std_Logic (Res.Mem, Len - I, Compute_Sum (Carry, Rb, Lb));
Carry := Compute_Carry (Carry, Rb, Lb);
if Signed then
V := Shift_Right_Arithmetic (V, 1);
else
V := Shift_Right (V, 1);
end if;
end loop;
return Res;
end Sub_Int_Vec;
function Sub_Nat_Uns (L : Uns64; R : Memtyp; Loc : Location_Type)
return Memtyp is
begin
return Sub_Int_Vec (L, R, False, Loc);
end Sub_Nat_Uns;
function Sub_Int_Sgn (L : Int64; R : Memtyp; Loc : Location_Type)
return Memtyp is
begin
return Sub_Int_Vec (To_Uns64 (L), R, True, Loc);
end Sub_Int_Sgn;
function Mul_Uns_Uns (L, R : Memtyp; Loc : Location_Type) return Memtyp
is
Llen : constant Uns32 := L.Typ.Abound.Len;
Rlen : constant Uns32 := R.Typ.Abound.Len;
Len : constant Uns32 := Llen + Rlen;
Res : Memtyp;
Lb, Rb, Vb, Carry : Sl_X01;
begin
Res.Typ := Create_Res_Type (L.Typ, Len);
Res := Create_Memory (Res.Typ);
if Llen = 0 or Rlen = 0 then
return Res;
end if;
Fill (Res, '0');
-- Shift and add L.
for I in 1 .. Rlen loop
Rb := Sl_To_X01 (Read_Std_Logic (R.Mem, Rlen - I));
if Rb = '1' then
-- Compute res := res + shift_left (l, i).
Carry := '0';
for J in 1 .. Llen loop
Lb := Read_Std_Logic (L.Mem, Llen - J);
Vb := Read_Std_Logic (Res.Mem, Len - (I + J - 1));
Write_Std_Logic
(Res.Mem, Len - (I + J - 1), Compute_Sum (Carry, Vb, Lb));
Carry := Compute_Carry (Carry, Vb, Lb);
end loop;
-- Propagate carry.
for J in I + Llen .. Len loop
exit when Carry = '0';
Vb := Read_Std_Logic (Res.Mem, Len - J);
Write_Std_Logic (Res.Mem, Len - J, Xor_Table (Carry, Vb));
Carry := And_Table (Carry, Vb);
end loop;
elsif Rb = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""*"": non logical value detected");
Fill (Res, 'X');
exit;
end if;
end loop;
return Res;
end Mul_Uns_Uns;
function To_Unsigned (Val : Uns64; Vtyp : Type_Acc) return Memtyp
is
Vlen : constant Uns32 := Vtyp.Abound.Len;
Res : Memtyp;
E : Std_Ulogic;
begin
Res := Create_Memory (Vtyp);
for I in 1 .. Vlen loop
if (Shift_Right (Val, Natural (I - 1)) and 1) = 0 then
E := '0';
else
E := '1';
end if;
Write_Std_Logic (Res.Mem, Vlen - I, E);
end loop;
return Res;
end To_Unsigned;
function Mul_Nat_Uns (L : Uns64; R : Memtyp; Loc : Location_Type)
return Memtyp
is
Lv : Memtyp;
begin
if R.Typ.Abound.Len = 0 then
return Create_Memory (R.Typ); -- FIXME: typ
end if;
Lv := To_Unsigned (L, R.Typ);
return Mul_Uns_Uns (Lv, R, Loc);
end Mul_Nat_Uns;
function Mul_Uns_Nat (L : Memtyp; R : Uns64; Loc : Location_Type)
return Memtyp
is
Rv : Memtyp;
begin
if L.Typ.Abound.Len = 0 then
return Create_Memory (L.Typ); -- FIXME: typ
end if;
Rv := To_Unsigned (R, L.Typ);
return Mul_Uns_Uns (L, Rv, Loc);
end Mul_Uns_Nat;
function Mul_Sgn_Sgn (L, R : Memtyp; Loc : Location_Type) return Memtyp
is
Llen : constant Uns32 := L.Typ.Abound.Len;
Rlen : constant Uns32 := R.Typ.Abound.Len;
Len : constant Uns32 := Llen + Rlen;
Res : Memtyp;
Lb, Rb, Vb, Carry : Sl_X01;
begin
Res.Typ := Create_Res_Type (L.Typ, Len);
Res := Create_Memory (Res.Typ);
if Llen = 0 or Rlen = 0 then
return Res;
end if;
Fill (Res, '0');
if Has_0x (L) = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""*"": non logical value detected");
Fill (Res, 'X');
return Res;
end if;
-- Shift and add L, do not consider (yet) the sign bit of R.
for I in 1 .. Rlen - 1 loop
Rb := Sl_To_X01 (Read_Std_Logic (R.Mem, Rlen - I));
if Rb = '1' then
-- Compute res := res + shift_left (l, i).
Carry := '0';
for J in 1 .. Llen loop
Lb := Sl_To_X01 (Read_Std_Logic (L.Mem, Llen - J));
Vb := Read_Std_Logic (Res.Mem, Len - (I + J - 1));
Write_Std_Logic
(Res.Mem, Len - (I + J - 1), Compute_Sum (Carry, Vb, Lb));
Carry := Compute_Carry (Carry, Vb, Lb);
end loop;
-- Sign extend and propagate carry.
Lb := Read_Std_Logic (L.Mem, 0);
for J in I + Llen .. Len loop
Vb := Sl_To_X01 (Read_Std_Logic (Res.Mem, Len - J));
Write_Std_Logic (Res.Mem, Len - J, Compute_Sum (Carry, Vb, Lb));
Carry := Compute_Carry (Carry, Vb, Lb);
end loop;
elsif Rb = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""*"": non logical value detected");
Fill (Res, 'X');
return Res;
end if;
end loop;
if Read_Std_Logic (R.Mem, 0) = '1' then
-- R is a negative number. It is considered as:
-- -2**n + (Rn-1 Rn-2 ... R0).
-- Compute res := res - 2**n * l.
Carry := '1';
for I in 1 .. Llen loop
-- Start at len - (rlen - 1) = llen + 1
Vb := Read_Std_Logic (Res.Mem, Llen - I + 1);
Lb := Not_Table (Read_Std_Logic (L.Mem, Llen - I));
Write_Std_Logic
(Res.Mem, Llen - I + 1, Compute_Sum (Carry, Vb, Lb));
Carry := Compute_Carry (Carry, Vb, Lb);
end loop;
-- The last bit.
Vb := Read_Std_Logic (Res.Mem, 0);
Lb := Not_Table (Read_Std_Logic (L.Mem, 0));
Write_Std_Logic (Res.Mem, 0, Compute_Sum (Carry, Vb, Lb));
end if;
return Res;
end Mul_Sgn_Sgn;
function To_Signed (Val : Int64; Vtyp : Type_Acc) return Memtyp
is
Vlen : constant Uns32 := Vtyp.Abound.Len;
Uval : constant Uns64 := To_Uns64 (Val);
Res : Memtyp;
E : Std_Ulogic;
begin
Res := Create_Memory (Vtyp);
for I in 1 .. Vlen loop
if (Shift_Right_Arithmetic (Uval, Natural (I - 1)) and 1) = 0 then
E := '0';
else
E := '1';
end if;
Write_Std_Logic (Res.Mem, Vlen - I, E);
end loop;
return Res;
end To_Signed;
function Mul_Int_Sgn (L : Int64; R : Memtyp; Loc : Location_Type)
return Memtyp
is
Lv : Memtyp;
begin
if R.Typ.Abound.Len = 0 then
return Create_Memory (R.Typ); -- FIXME: typ
end if;
Lv := To_Signed (L, R.Typ);
return Mul_Sgn_Sgn (Lv, R, Loc);
end Mul_Int_Sgn;
function Mul_Sgn_Int (L : Memtyp; R : Int64; Loc : Location_Type)
return Memtyp
is
Rv : Memtyp;
begin
if L.Typ.Abound.Len = 0 then
return Create_Memory (L.Typ); -- FIXME: typ
end if;
Rv := To_Signed (R, L.Typ);
return Mul_Sgn_Sgn (L, Rv, Loc);
end Mul_Sgn_Int;
function Neg_Vec_Notyp (V : Memtyp) return Memory_Ptr
is
Res : Memory_Ptr;
begin
Res := Alloc_Memory (V.Typ, Current_Pool);
Neg_Vec (V.Mem, Res, V.Typ.Abound.Len);
return Res;
end Neg_Vec_Notyp;
procedure Neg_Vec (V : Memtyp) is
begin
Neg_Vec (V.Mem, V.Mem, V.Typ.Abound.Len);
end Neg_Vec;
function Neg_Vec (V : Memtyp; Loc : Location_Type) return Memtyp
is
Len : constant Uns32 := V.Typ.Abound.Len;
Res : Memtyp;
begin
Res.Typ := Create_Res_Type (V.Typ, Len);
Res := Create_Memory (Res.Typ);
if Len = 0 then
return Res;
end if;
if Has_0x (V) = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""-"": non logical value detected");
Fill (Res, 'X');
else
Neg_Vec (V.Mem, Res.Mem, V.Typ.Abound.Len);
end if;
return Res;
end Neg_Vec;
procedure To_01X (Src : Memory_Ptr; Dst : Memory_Ptr; Len : Uns32)
is
V : Sl_X01;
begin
for I in 1 .. Len loop
V := Sl_To_X01 (Read_Std_Logic (Src, Len - I));
if V = 'X' then
for J in 1 .. Len loop
Write_Std_Logic (Dst, J - 1, 'X');
end loop;
return;
end if;
Write_Std_Logic (Dst, Len - I, V);
end loop;
end To_01X;
function Abs_Vec (V : Memtyp; Loc : Location_Type) return Memtyp
is
pragma Unreferenced (Loc);
Len : constant Uns32 := V.Typ.Abound.Len;
Res : Memtyp;
Msb : Sl_X01;
begin
Res.Typ := Create_Res_Type (V.Typ, Len);
Res := Create_Memory (Res.Typ);
if Len = 0 then
return Res;
end if;
-- Convert to 01, check for X.
To_01X (V.Mem, Res.Mem, Len);
Msb := Read_Std_Logic (Res.Mem, 0);
if Msb = '1' then
Neg_Vec (Res);
end if;
return Res;
end Abs_Vec;
function Shift_Vec (Val : Memtyp;
Amt : Uns32;
Right : Boolean;
Arith : Boolean) return Memtyp
is
Len : constant Uns32 := Uns32 (Vec_Length (Val.Typ));
Res : Memtyp;
Pad, B : Std_Ulogic;
begin
Res.Typ := Create_Res_Type (Val.Typ, Len);
Res := Create_Memory (Res.Typ);
if Len = 0 then
return Res;
end if;
if Arith then
Pad := Read_Std_Logic (Val.Mem, 0);
else
Pad := '0';
end if;
if Amt >= Len then
if Right then
Fill (Res, Pad);
else
Fill (Res, '0');
end if;
return Res;
end if;
if Right then
for I in 1 .. Amt loop
Write_Std_Logic (Res.Mem, I - 1, Pad);
end loop;
for I in Amt + 1 .. Len loop
B := Read_Std_Logic (Val.Mem, I - 1 - Amt);
Write_Std_Logic (Res.Mem, I - 1, B);
end loop;
else
for I in 1 .. Len - Amt loop
B := Read_Std_Logic (Val.Mem, Amt + I - 1);
Write_Std_Logic (Res.Mem, I - 1, B);
end loop;
for I in Len - Amt + 1 .. Len loop
Write_Std_Logic (Res.Mem, I - 1, Pad);
end loop;
end if;
return Res;
end Shift_Vec;
function Rotate_Vec (Val : Memtyp;
Amt : Uns32;
Right : Boolean) return Memtyp
is
Len : constant Uns32 := Uns32 (Vec_Length (Val.Typ));
Cnt : Uns32;
Res : Memtyp;
B : Std_Ulogic;
begin
Res.Typ := Create_Res_Type (Val.Typ, Len);
Res := Create_Memory (Res.Typ);
if Len = 0 then
return Res;
end if;
Cnt := Amt rem Len;
pragma Unreferenced (Amt);
if Right then
for I in 1 .. Len - Cnt loop
B := Read_Std_Logic (Val.Mem, I - 1);
Write_Std_Logic (Res.Mem, Cnt + I - 1, B);
end loop;
for I in 1 .. Cnt loop
B := Read_Std_Logic (Val.Mem, Len - I);
Write_Std_Logic (Res.Mem, Cnt - I, B);
end loop;
else
for I in 1 .. Cnt loop
B := Read_Std_Logic (Val.Mem, I - 1);
Write_Std_Logic (Res.Mem, Len - Cnt + I - 1, B);
end loop;
for I in 1 .. Len - Cnt loop
B := Read_Std_Logic (Val.Mem, Len - I);
Write_Std_Logic (Res.Mem, Len - Cnt - I, B);
end loop;
end if;
return Res;
end Rotate_Vec;
procedure Resize_Vec (Dest : Memtyp; Val : Memtyp; Signed : Boolean)
is
Size : constant Uns32 := Dest.Typ.Abound.Len;
Old_Size : constant Uns32 := Val.Typ.Abound.Len;
L : Uns32;
Pad, B : Std_Ulogic;
begin
if Size = 0 then
return;
end if;
if Signed and then Old_Size > 0 then
Pad := Read_Std_Logic (Val.Mem, 0);
Write_Std_Logic (Dest.Mem, 0, Pad);
L := Size - 1;
else
Pad := '0';
L := Size;
end if;
for I in 1 .. L loop
if I <= Old_Size then
B := Read_Std_Logic (Val.Mem, Old_Size - I);
else
B := Pad;
end if;
Write_Std_Logic (Dest.Mem, Size - I, B);
end loop;
end Resize_Vec;
function Resize_Vec (Val : Memtyp;
Size : Uns32;
Signed : Boolean) return Memtyp
is
Res : Memtyp;
begin
Res.Typ := Create_Res_Type (Val.Typ, Size);
Res := Create_Memory (Res.Typ);
Resize_Vec (Res, Val, Signed);
return Res;
end Resize_Vec;
type Std_Logic_Vector_Type is array (Uns32 range <>) of Std_Ulogic;
procedure Divmod (Num, Dem : Memtyp; Quot, Remain : Memtyp)
is
Nlen : constant Uns32 := Num.Typ.Abound.Len;
Dlen : constant Uns32 := Dem.Typ.Abound.Len;
pragma Assert (Nlen > 0);
pragma Assert (Dlen > 0);
pragma Assert (Quot.Typ = null or else Quot.Typ.Abound.Len = Nlen);
Reg : Std_Logic_Vector_Type (0 .. Dlen);
Sub : Std_Logic_Vector_Type (0 .. Dlen - 1);
Carry : Sl_X01;
D : Sl_X01;
begin
Reg := (others => '0');
Sub := (others => '0');
-- Stupid pen and paper division algorithm.
for I in 0 .. Nlen - 1 loop
-- Shift
Reg (0 .. Dlen - 1) := Reg (1 .. Dlen);
Reg (Dlen) := Sl_To_X01 (Read_Std_Logic (Num.Mem, I));
-- Substract
Carry := '1';
for J in reverse 0 .. Dlen - 1 loop
D := Not_Table (Read_Std_Logic (Dem.Mem, J));
Sub (J) := Compute_Sum (Carry, Reg (J + 1), D);
Carry := Compute_Carry (Carry, Reg (J + 1), D);
end loop;
-- Extra REG bit.
Carry := Compute_Carry (Carry, Reg (0), '1');
-- Test
if Quot.Mem /= null then
Write_Std_Logic (Quot.Mem, I, Carry);
end if;
if Carry = '1' then
Reg (0) := '0';
Reg (1 .. Dlen) := Sub;
end if;
end loop;
if Remain /= Null_Memtyp then
pragma Assert (Remain.Typ.Abound.Len = Dlen);
for I in 0 .. Dlen - 1 loop
Write_Std_Logic (Remain.Mem, I, Reg (I + 1));
end loop;
end if;
end Divmod;
function Div_Uns_Uns (Inst : Synth_Instance_Acc;
L, R : Memtyp;
Loc : Node) return Memtyp
is
Nlen : constant Uns32 := L.Typ.Abound.Len;
Dlen : constant Uns32 := R.Typ.Abound.Len;
Quot : Memtyp;
R0 : Sl_X01;
begin
Quot.Typ := Create_Res_Type (L.Typ, Nlen);
Quot := Create_Memory (Quot.Typ);
if Nlen = 0 or Dlen = 0 then
return Quot;
end if;
R0 := Has_0x (R);
if Has_0x (L) = 'X' or R0 = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""/"": non logical value detected");
Fill (Quot, 'X');
return Quot;
end if;
if R0 = '0' then
Error_Msg_Synth (Inst, Loc, "NUMERIC_STD.""/"": division by 0");
Fill (Quot, 'X');
return Quot;
end if;
Divmod (L, R, Quot, Null_Memtyp);
return Quot;
end Div_Uns_Uns;
function Div_Uns_Nat (Inst : Synth_Instance_Acc;
L : Memtyp;
R : Uns64;
Loc : Node) return Memtyp
is
Rv : Memtyp;
begin
if L.Typ.Abound.Len = 0 then
return Create_Memory (L.Typ); -- FIXME: typ
end if;
Rv := To_Unsigned (R, L.Typ);
return Div_Uns_Uns (Inst, L, Rv, Loc);
end Div_Uns_Nat;
function Div_Nat_Uns (Inst : Synth_Instance_Acc;
L : Uns64;
R : Memtyp;
Loc : Node) return Memtyp
is
Lv : Memtyp;
begin
if R.Typ.Abound.Len = 0 then
return Create_Memory (R.Typ); -- FIXME: typ
end if;
Lv := To_Unsigned (L, R.Typ);
return Div_Uns_Uns (Inst, Lv, R, Loc);
end Div_Nat_Uns;
function Div_Sgn_Sgn (Inst : Synth_Instance_Acc;
L, R : Memtyp;
Loc : Node) return Memtyp
is
Nlen : constant Uns32 := L.Typ.Abound.Len;
Dlen : constant Uns32 := R.Typ.Abound.Len;
Quot : Memtyp;
R0 : Sl_X01;
Lu : Memtyp;
Ru : Memtyp;
Neg : Boolean;
begin
Quot.Typ := Create_Res_Type (L.Typ, Nlen);
Quot := Create_Memory (Quot.Typ);
if Nlen = 0 or Dlen = 0 then
return Quot;
end if;
R0 := Has_0x (R);
if Has_0x (L) = 'X' or R0 = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""/"": non logical value detected");
Fill (Quot, 'X');
return Quot;
end if;
if R0 = '0' then
Error_Msg_Synth (Inst, Loc, "NUMERIC_STD.""/"": division by 0");
Fill (Quot, 'X');
return Quot;
end if;
if To_X01 (Read_Std_Logic (L.Mem, 0)) = '1' then
Lu.Typ := L.Typ;
Lu.Mem := Neg_Vec_Notyp (L);
Neg := True;
else
Lu := L;
Neg := False;
end if;
if To_X01 (Read_Std_Logic (R.Mem, 0)) = '1' then
Ru.Typ := R.Typ;
Ru.Mem := Neg_Vec_Notyp (R);
Neg := not Neg;
else
Ru := R;
end if;
Divmod (Lu, Ru, Quot, Null_Memtyp);
if Neg then
Neg_Vec (Quot);
end if;
return Quot;
end Div_Sgn_Sgn;
function Div_Sgn_Int (Inst : Synth_Instance_Acc;
L : Memtyp;
R : Int64;
Loc : Node) return Memtyp
is
Rv : Memtyp;
begin
if L.Typ.Abound.Len = 0 then
return Create_Memory (L.Typ); -- FIXME: typ
end if;
Rv := To_Signed (R, L.Typ);
return Div_Sgn_Sgn (Inst, L, Rv, Loc);
end Div_Sgn_Int;
function Div_Int_Sgn (Inst : Synth_Instance_Acc;
L : Int64;
R : Memtyp;
Loc : Node) return Memtyp
is
Lv : Memtyp;
begin
if R.Typ.Abound.Len = 0 then
return Create_Memory (R.Typ); -- FIXME: typ
end if;
Lv := To_Signed (L, R.Typ);
return Div_Sgn_Sgn (Inst, Lv, R, Loc);
end Div_Int_Sgn;
function Rem_Uns_Uns (Inst : Synth_Instance_Acc;
L, R : Memtyp;
Loc : Node) return Memtyp
is
Nlen : constant Uns32 := L.Typ.Abound.Len;
Dlen : constant Uns32 := R.Typ.Abound.Len;
Rema : Memtyp;
R0 : Sl_X01;
begin
Rema.Typ := Create_Res_Type (R.Typ, Dlen);
Rema := Create_Memory (Rema.Typ);
if Nlen = 0 or Dlen = 0 then
return Rema;
end if;
R0 := Has_0x (R);
if Has_0x (L) = 'X' or R0 = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""rem"": non logical value detected");
Fill (Rema, 'X');
return Rema;
end if;
if R0 = '0' then
Error_Msg_Synth (Inst, Loc, "NUMERIC_STD.""rem"": division by 0");
Fill (Rema, 'X');
return Rema;
end if;
Divmod (L, R, Null_Memtyp, Rema);
return Rema;
end Rem_Uns_Uns;
function Rem_Uns_Nat (Inst : Synth_Instance_Acc;
L : Memtyp;
R : Uns64;
Loc : Node) return Memtyp
is
Rv : Memtyp;
begin
if L.Typ.Abound.Len = 0 then
return Create_Memory (L.Typ); -- FIXME: typ
end if;
Rv := To_Unsigned (R, L.Typ);
return Rem_Uns_Uns (Inst, L, Rv, Loc);
end Rem_Uns_Nat;
function Rem_Nat_Uns (Inst : Synth_Instance_Acc;
L : Uns64;
R : Memtyp;
Loc : Node) return Memtyp
is
Lv : Memtyp;
begin
if R.Typ.Abound.Len = 0 then
return Create_Memory (R.Typ); -- FIXME: typ
end if;
Lv := To_Unsigned (L, R.Typ);
return Rem_Uns_Uns (Inst, Lv, R, Loc);
end Rem_Nat_Uns;
function Rem_Sgn_Sgn (Inst : Synth_Instance_Acc;
L, R : Memtyp;
Loc : Node) return Memtyp
is
Nlen : constant Uns32 := L.Typ.Abound.Len;
Dlen : constant Uns32 := R.Typ.Abound.Len;
Rema : Memtyp;
R0 : Sl_X01;
Lu : Memtyp;
Ru : Memtyp;
Neg : Boolean;
begin
Rema.Typ := Create_Res_Type (L.Typ, Dlen);
Rema := Create_Memory (Rema.Typ);
if Nlen = 0 or Dlen = 0 then
return Rema;
end if;
R0 := Has_0x (R);
if Has_0x (L) = 'X' or R0 = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""rem"": non logical value detected");
Fill (Rema, 'X');
return Rema;
end if;
if R0 = '0' then
Error_Msg_Synth (Inst, Loc, "NUMERIC_STD.""rem"": division by 0");
Fill (Rema, 'X');
return Rema;
end if;
if To_X01 (Read_Std_Logic (L.Mem, 0)) = '1' then
Lu.Typ := L.Typ;
Lu.Mem := Neg_Vec_Notyp (L);
Neg := True;
else
Neg := False;
Lu := L;
end if;
if To_X01 (Read_Std_Logic (R.Mem, 0)) = '1' then
Ru.Typ := R.Typ;
Ru.Mem := Neg_Vec_Notyp (R);
else
Ru := R;
end if;
Divmod (Lu, Ru, Null_Memtyp, Rema);
-- Result of rem has the sign of the dividend.
if Neg then
Neg_Vec (Rema);
end if;
return Rema;
end Rem_Sgn_Sgn;
function Rem_Sgn_Int (Inst : Synth_Instance_Acc;
L : Memtyp;
R : Int64;
Loc : Node) return Memtyp
is
Rv : Memtyp;
begin
if L.Typ.Abound.Len = 0 then
return Create_Memory (L.Typ); -- FIXME: typ
end if;
Rv := To_Signed (R, L.Typ);
return Rem_Sgn_Sgn (Inst, L, Rv, Loc);
end Rem_Sgn_Int;
function Rem_Int_Sgn (Inst : Synth_Instance_Acc;
L : Int64;
R : Memtyp;
Loc : Node) return Memtyp
is
Lv : Memtyp;
begin
if R.Typ.Abound.Len = 0 then
return Create_Memory (R.Typ); -- FIXME: typ
end if;
Lv := To_Signed (L, R.Typ);
return Rem_Sgn_Sgn (Inst, Lv, R, Loc);
end Rem_Int_Sgn;
function Mod_Sgn_Sgn (Inst : Synth_Instance_Acc;
L, R : Memtyp;
Loc : Node) return Memtyp
is
Nlen : constant Uns32 := L.Typ.Abound.Len;
Dlen : constant Uns32 := R.Typ.Abound.Len;
Rema : Memtyp;
R0 : Sl_X01;
Lu : Memtyp;
Ru : Memtyp;
L_Neg, R_Neg : Boolean;
begin
Rema.Typ := Create_Res_Type (L.Typ, Dlen);
Rema := Create_Memory (Rema.Typ);
if Nlen = 0 or Dlen = 0 then
return Rema;
end if;
R0 := Has_0x (R);
if Has_0x (L) = 'X' or R0 = 'X' then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.""rem"": non logical value detected");
Fill (Rema, 'X');
return Rema;
end if;
if R0 = '0' then
Error_Msg_Synth (Inst, Loc, "NUMERIC_STD.""rem"": division by 0");
Fill (Rema, 'X');
return Rema;
end if;
if To_X01 (Read_Std_Logic (L.Mem, 0)) = '1' then
Lu.Typ := L.Typ;
Lu.Mem := Neg_Vec_Notyp (L);
L_Neg := True;
else
Lu := L;
L_Neg := False;
end if;
if To_X01 (Read_Std_Logic (R.Mem, 0)) = '1' then
Ru.Typ := R.Typ;
Ru.Mem := Neg_Vec_Notyp (R);
R_Neg := True;
else
Ru := R;
R_Neg := False;
end if;
Divmod (Lu, Ru, Null_Memtyp, Rema);
if Has_0x (Rema) = '0' then
-- If the remainder is 0, then the modulus is 0.
return Rema;
else
-- Result of rem has the sign of the divisor.
if R_Neg then
if L_Neg then
Neg_Vec (Rema);
return Rema;
else
return Add_Vec_Vec (R, Rema, True, +Loc);
end if;
else
if L_Neg then
return Sub_Vec_Vec (R, Rema, True, +Loc);
else
return Rema;
end if;
end if;
end if;
end Mod_Sgn_Sgn;
function Mod_Sgn_Int (Inst : Synth_Instance_Acc;
L : Memtyp;
R : Int64;
Loc : Node) return Memtyp
is
Rv : Memtyp;
begin
if L.Typ.Abound.Len = 0 then
return Create_Memory (L.Typ); -- FIXME: typ
end if;
Rv := To_Signed (R, L.Typ);
return Mod_Sgn_Sgn (Inst, L, Rv, Loc);
end Mod_Sgn_Int;
function Mod_Int_Sgn (Inst : Synth_Instance_Acc;
L : Int64;
R : Memtyp;
Loc : Node) return Memtyp
is
Lv : Memtyp;
begin
if R.Typ.Abound.Len = 0 then
return Create_Memory (R.Typ); -- FIXME: typ
end if;
Lv := To_Signed (L, R.Typ);
return Mod_Sgn_Sgn (Inst, Lv, R, Loc);
end Mod_Int_Sgn;
function Minmax (L, R : Memtyp; Is_Signed : Boolean; Is_Max : Boolean)
return Memtyp
is
Len : constant Uns32 := Uns32'Max (L.Typ.Abound.Len, R.Typ.Abound.Len);
Res : Memtyp;
Lt : Boolean;
begin
if L.Typ.Abound.Len = 0 or R.Typ.Abound.Len = 0 then
Res.Typ := Create_Res_Type (L.Typ, 0);
Res := Create_Memory (Res.Typ);
return Res;
end if;
Res.Typ := Create_Res_Type (L.Typ, Len);
Res := Create_Memory (Res.Typ);
if Has_0x (L) = 'X' or else Has_0x (R) = 'X' then
Fill (Res, 'X');
return Res;
end if;
if Is_Signed then
Lt := Compare_Sgn_Sgn (L, R, Less, No_Location) = Less;
else
Lt := Compare_Uns_Uns (L, R, Less, No_Location) = Less;
end if;
if Lt xor Is_Max then
Resize_Vec (Res, L, False);
else
Resize_Vec (Res, R, False);
end if;
return Res;
end Minmax;
function Offset_To_Index (Off : Int32; Typ : Type_Acc) return Int32 is
begin
case Typ.Abound.Dir is
when Dir_To =>
return Typ.Abound.Left + Off;
when Dir_Downto =>
return Typ.Abound.Left - Off;
end case;
end Offset_To_Index;
function Find_Rightmost (Arg : Memtyp; Val : Memtyp) return Int32
is
Len : constant Uns32 := Arg.Typ.Abound.Len;
Y : Std_Ulogic;
begin
Y := Read_Std_Logic (Val.Mem, 0);
for I in reverse 1 .. Len loop
if Match_Eq_Table (Read_Std_Logic (Arg.Mem, I - 1), Y) = '1' then
return Offset_To_Index (Int32 (I - 1), Arg.Typ);
end if;
end loop;
return -1;
end Find_Rightmost;
function Find_Leftmost (Arg : Memtyp; Val : Memtyp) return Int32
is
Len : constant Uns32 := Arg.Typ.Abound.Len;
Y : Std_Ulogic;
begin
Y := Read_Std_Logic (Val.Mem, 0);
for I in 1 .. Len loop
if Match_Eq_Table (Read_Std_Logic (Arg.Mem, I - 1), Y) = '1' then
return Offset_To_Index (Int32 (I - 1), Arg.Typ);
end if;
end loop;
return -1;
end Find_Leftmost;
function Match_Vec (L, R : Memtyp; Loc : Location_Type) return Boolean
is
Llen : constant Uns32 := L.Typ.Abound.Len;
Rlen : constant Uns32 := R.Typ.Abound.Len;
begin
if Llen = 0 or Rlen = 0 then
Warn_Compare_Null (Loc);
return False;
end if;
if Llen /= Rlen then
Warning_Msg_Synth
(+Loc, "NUMERIC_STD.STD_MATCH: length mismatch, returning FALSE");
return False;
end if;
for I in 1 .. Llen loop
if Match_Eq_Table (Read_Std_Logic (L.Mem, I - 1),
Read_Std_Logic (R.Mem, I - 1)) /= '1'
then
return False;
end if;
end loop;
return True;
end Match_Vec;
function Match_Eq_Vec_Vec (Left, Right : Memtyp;
Is_Signed : Boolean;
Loc : Location_Type) return Std_Ulogic
is
Lw : constant Uns32 := Left.Typ.W;
Rw : constant Uns32 := Right.Typ.W;
Len : constant Uns32 := Uns32'Max (Left.Typ.W, Right.Typ.W);
L, R, T : Std_Ulogic;
Res : Std_Ulogic;
begin
if Len = 0 then
Warn_Compare_Null (Loc);
return 'X';
end if;
Res := '1';
for I in 1 .. Len loop
if I > Lw then
if not Is_Signed then
L := '0';
end if;
else
L := Read_Std_Logic (Left.Mem, Lw - I);
end if;
if I > Rw then
if not Is_Signed then
R := '0';
end if;
else
R := Read_Std_Logic (Right.Mem, Rw - I);
end if;
T := Match_Eq_Table (L, R);
if T = 'U' then
return T;
elsif T = 'X' or Res = 'X' then
-- Lower priority than 'U'.
Res := 'X';
elsif T = '0' then
Res := '0';
end if;
end loop;
return Res;
end Match_Eq_Vec_Vec;
function Has_Xd (V : Memtyp) return Std_Ulogic
is
Res : Std_Ulogic;
E : Std_Ulogic;
begin
Res := '0';
for I in 0 .. V.Typ.Abound.Len - 1 loop
E := Read_Std_Logic (V.Mem, I);
if E = '-' then
return '-';
elsif To_X01 (E) = 'X' then
Res := 'X';
end if;
end loop;
return Res;
end Has_Xd;
function Match_Cmp_Vec_Vec (Left, Right : Memtyp;
Map : Order_Map_Type;
Is_Signed : Boolean;
Loc : Location_Type) return Memtyp
is
Llen : constant Uns32 := Left.Typ.Abound.Len;
Rlen : constant Uns32 := Right.Typ.Abound.Len;
L, R : Std_Ulogic;
Res : Std_Ulogic;
Cmp : Order_Type;
begin
if Rlen = 0 or Llen = 0 then
Warn_Compare_Null (Loc);
Res := 'X';
else
L := Has_Xd (Left);
R := Has_Xd (Right);
if L = '-' or R = '-' then
Warning_Msg_Synth (+Loc, "'-' found in compare string");
Res := 'X';
elsif L = 'X' or R = 'X' then
Res := 'X';
else
if Is_Signed then
Cmp := Compare_Sgn_Sgn (Left, Right, Equal, Loc);
else
Cmp := Compare_Uns_Uns (Left, Right, Equal, Loc);
end if;
Res := Map (Cmp);
end if;
end if;
return Create_Memory_U8 (Std_Ulogic'Pos (Res), Logic_Type);
end Match_Cmp_Vec_Vec;
end Synth.Ieee.Numeric_Std;
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