📄 mul.vhd
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----------------------------------------------------------------------------
-- This file is a part of the LEON VHDL model
-- Copyright (C) 1999 European Space Agency (ESA)
--
-- This library is free software; you can redistribute it and/or
-- modify it under the terms of the GNU Lesser General Public
-- License as published by the Free Software Foundation; either
-- version 2 of the License, or (at your option) any later version.
--
-- See the file COPYING.LGPL for the full details of the license.
-----------------------------------------------------------------------------
-- Entity: mul
-- File: mul.vhd
-- Author: Jiri Gaisler - Gaisler Research
-- Description: This unit implemets integer multiply and optionally the
-- UMUL/SMUL/UMAC/SMAC instructions.
------------------------------------------------------------------------------
library IEEE;
use IEEE.std_logic_1164.all;
use IEEE.std_logic_unsigned."+";
use work.leon_target.all;
use work.leon_config.all;
use work.leon_iface.all;
use work.tech_map.all;
entity mul is
port (
rst : in std_logic;
clk : in clk_type;
holdn : in std_logic;
muli : in mul_in_type;
mulo : out mul_out_type
);
end;
architecture rtl of mul is
type mul_regtype is record
acc : std_logic_vector(63 downto 0);
state : std_logic_vector(1 downto 0);
start : std_logic;
ready : std_logic;
end record;
type mac_regtype is record
mac : std_logic;
signed : std_logic;
end record;
signal rm, rmin : mul_regtype;
signal mm, mmin : mac_regtype;
signal ma, mb : std_logic_vector(32 downto 0);
signal prod : std_logic_vector(65 downto 0);
signal mreg : std_logic_vector(49 downto 0);
begin
mulcomb : process(rst, rm, muli, mreg, prod, mm)
variable mop1, mop2 : std_logic_vector(32 downto 0);
variable acc, acc1, acc2 : std_logic_vector(48 downto 0);
variable zero : std_logic;
variable v : mul_regtype;
variable w : mac_regtype;
constant CZero: std_logic_vector(47 downto 0) := "000000000000000000000000000000000000000000000000";
begin
v := rm; w := mm; v.start := muli.start; v.ready := '0';
mop1 := muli.op1; mop2 := muli.op2;
acc1 := (others => '0'); acc2 := (others => '0');
w.mac := muli.mac; w.signed := muli.signed; zero := '0';
-- select input 2 to accumulator
case MULTIPLIER is
when m16x16 =>
acc2(32 downto 0) := mreg(32 downto 0);
when m32x8 =>
acc2(40 downto 0) := mreg(40 downto 0);
when m32x16 =>
acc2(48 downto 0) := mreg(48 downto 0);
when others => null;
end case;
-- state machine + inputs to multiplier and accumulator input 1
case rm.state is
when "00" =>
case MULTIPLIER is
when m16x16 =>
mop1(16 downto 0) := '0' & muli.op1(15 downto 0);
mop2(16 downto 0) := '0' & muli.op2(15 downto 0);
if MULPIPE and (rm.ready = '1' ) then
acc1(32 downto 0) := rm.acc(48 downto 16);
else acc1(32 downto 0) := '0' & rm.acc(63 downto 32); end if;
when m32x8 =>
mop1 := muli.op1;
mop2(8 downto 0) := '0' & muli.op2(7 downto 0);
acc1(40 downto 0) := '0' & rm.acc(63 downto 24);
when m32x16 =>
mop1 := muli.op1;
mop2(16 downto 0) := '0' & muli.op2(15 downto 0);
acc1(48 downto 0) := '0' & rm.acc(63 downto 16);
when others => null;
end case;
if (rm.start = '1') then v.state := "01"; end if;
when "01" =>
case MULTIPLIER is
when m16x16 =>
mop1(16 downto 0) := muli.op1(32 downto 16);
mop2(16 downto 0) := '0' & muli.op2(15 downto 0);
if MULPIPE then acc1(32 downto 0) := '0' & rm.acc(63 downto 32); end if;
v.state := "10";
when m32x8 =>
mop1 := muli.op1; mop2(8 downto 0) := '0' & muli.op2(15 downto 8);
v.state := "10";
when m32x16 =>
mop1 := muli.op1; mop2(16 downto 0) := muli.op2(32 downto 16);
v.state := "00";
when others => null;
end case;
when "10" =>
case MULTIPLIER is
when m16x16 =>
mop1(16 downto 0) := '0' & muli.op1(15 downto 0);
mop2(16 downto 0) := muli.op2(32 downto 16);
if MULPIPE then acc1 := (others => '0'); acc2 := (others => '0');
else acc1(32 downto 0) := rm.acc(48 downto 16); end if;
v.state := "11";
when m32x8 =>
mop1 := muli.op1; mop2(8 downto 0) := '0' & muli.op2(23 downto 16);
acc1(40 downto 0) := rm.acc(48 downto 8);
v.state := "11";
when others => null;
end case;
when others =>
case MULTIPLIER is
when m16x16 =>
mop1(16 downto 0) := muli.op1(32 downto 16);
mop2(16 downto 0) := muli.op2(32 downto 16);
if MULPIPE then acc1(32 downto 0) := rm.acc(48 downto 16);
else acc1(32 downto 0) := rm.acc(48 downto 16); end if;
v.state := "00";
when m32x8 =>
mop1 := muli.op1; mop2(8 downto 0) := muli.op2(32 downto 24);
acc1(40 downto 0) := rm.acc(56 downto 16);
v.state := "00";
when others => null;
end case;
end case;
-- optional UMAC/SMAC support
if MACEN then
if ((muli.mac and muli.signed) = '1') then
mop1(16) := muli.op1(15); mop2(16) := muli.op2(15);
end if;
if mm.mac = '1' then
acc1(32 downto 0) := muli.y(0) & muli.asr18;
if mm.signed = '1' then acc2(39 downto 32) := (others => mreg(31));
else acc2(39 downto 32) := (others => '0'); end if;
end if;
acc1(39 downto 33) := muli.y(7 downto 1);
end if;
-- accumulator for iterative multiplication (and MAC)
-- pragma translate_off
if not (is_x(acc1 & acc2)) then
-- pragma translate_on
case MULTIPLIER is
when m16x16 =>
if MACEN then
acc(39 downto 0) := acc1(39 downto 0) + acc2(39 downto 0);
else
acc(32 downto 0) := acc1(32 downto 0) + acc2(32 downto 0);
end if;
when m32x8 =>
acc(40 downto 0) := acc1(40 downto 0) + acc2(40 downto 0);
when m32x16 =>
acc(48 downto 0) := acc1(48 downto 0) + acc2(48 downto 0);
when m32x32 =>
v.acc(31 downto 0) := prod(63 downto 32);
when others => null;
end case;
-- pragma translate_off
end if;
-- pragma translate_on
-- save intermediate result to accumulator
case rm.state is
when "00" =>
case MULTIPLIER is
when m16x16 =>
if MULPIPE and (rm.ready = '1' ) then
v.acc(48 downto 16) := acc(32 downto 0);
if muli.signed = '1' then
v.acc(63 downto 49) := (others => acc(32));
end if;
else
v.acc(63 downto 32) := acc(31 downto 0);
end if;
when m32x8 => v.acc(63 downto 24) := acc(39 downto 0);
when m32x16 => v.acc(63 downto 16) := acc(47 downto 0);
when others => null;
end case;
when "01" =>
case MULTIPLIER is
when m16x16 =>
if MULPIPE then v.acc := (others => '0');
else v.acc := CZero(31 downto 0) & mreg(31 downto 0); end if;
when m32x8 =>
v.acc := CZero(23 downto 0) & mreg(39 downto 0);
if muli.signed = '1' then v.acc(48 downto 40) := (others => acc(40)); end if;
when m32x16 =>
v.acc := CZero(15 downto 0) & mreg(47 downto 0); v.ready := '1';
if muli.signed = '1' then v.acc(63 downto 48) := (others => acc(48)); end if;
when others => null;
end case;
when "10" =>
case MULTIPLIER is
when m16x16 =>
if MULPIPE then
v.acc := CZero(31 downto 0) & mreg(31 downto 0);
else
v.acc(48 downto 16) := acc(32 downto 0);
end if;
when m32x8 => v.acc(48 downto 8) := acc(40 downto 0);
if muli.signed = '1' then v.acc(56 downto 49) := (others => acc(40)); end if;
when others => null;
end case;
when others =>
case MULTIPLIER is
when m16x16 =>
if MULPIPE then
v.acc(48 downto 16) := acc(32 downto 0);
else
v.acc(48 downto 16) := acc(32 downto 0);
if muli.signed = '1' then
v.acc(63 downto 49) := (others => acc(32));
end if;
end if;
v.ready := '1';
when m32x8 => v.acc(56 downto 16) := acc(40 downto 0); v.ready := '1';
if muli.signed = '1' then v.acc(63 downto 57) := (others => acc(40)); end if;
when others => null;
end case;
end case;
-- drive result and condition codes
if (rst = '0') or (muli.flush = '1') then v.state := "00"; v.start := '0'; end if;
rmin <= v; ma <= mop1; mb <= mop2; mmin <= w;
if MULPIPE then mulo.ready <= rm.ready; else mulo.ready <= v.ready; end if;
case MULTIPLIER is
when m16x16 =>
if rm.acc(31 downto 0) = CZero(31 downto 0) then zero := '1'; end if;
if MACEN and (mm.mac = '1') then
mulo.result(39 downto 0) <= acc(39 downto 0);
if mm.signed = '1' then
mulo.result(63 downto 40) <= (others => acc(39));
else
mulo.result(63 downto 40) <= (others => '0');
end if;
else
mulo.result(39 downto 0) <= v.acc(39 downto 32) & rm.acc(31 downto 0);
mulo.result(63 downto 40) <= v.acc(63 downto 40);
end if;
mulo.icc <= rm.acc(31) & zero & "00";
when m32x8 =>
if (rm.acc(23 downto 0) = CZero(23 downto 0)) and
(v.acc(31 downto 24) = CZero(7 downto 0))
then zero := '1'; end if;
mulo.result <= v.acc(63 downto 24) & rm.acc(23 downto 0);
mulo.icc <= v.acc(31) & zero & "00";
when m32x16 =>
if (rm.acc(15 downto 0) = CZero(15 downto 0)) and
(v.acc(31 downto 16) = CZero(15 downto 0))
then zero := '1'; end if;
mulo.result <= v.acc(63 downto 16) & rm.acc(15 downto 0);
mulo.icc <= v.acc(31) & zero & "00";
when m32x32 =>
mulo.result <= rm.acc(31 downto 0) & prod(31 downto 0);
mulo.icc <= "0000"; -- icc set in iu.vhd
when others => null;
mulo.result <= (others => '-');
mulo.icc <= (others => '-');
end case;
end process;
xm1616 : if MULTIPLIER = m16x16 generate
m0 : hw_smult generic map (17, 17)
port map (clk, holdn, ma(16 downto 0), mb(16 downto 0), prod(33 downto 0));
reg : process(clk)
begin
if rising_edge(clk) then
if (holdn = '1') then
if MACEN then mm <= mmin; end if;
mreg(33 downto 0) <= prod(33 downto 0);
end if;
end if;
end process;
end generate;
xm3208 : if MULTIPLIER = m32x8 generate
m0 : hw_smult generic map (33, 9)
port map (clk, holdn, ma(32 downto 0), mb(8 downto 0), prod(41 downto 0));
reg : process(clk)
begin
if rising_edge(clk) then
if (holdn = '1') then
mreg(41 downto 0) <= prod(41 downto 0);
end if;
end if;
end process;
end generate;
xm3216 : if MULTIPLIER = m32x16 generate
m0 : hw_smult generic map (33, 17)
port map (clk, holdn, ma(32 downto 0), mb(16 downto 0), prod(49 downto 0));
reg : process(clk)
begin
if rising_edge(clk) then
if (holdn = '1') then
mreg(49 downto 0) <= prod(49 downto 0);
end if;
end if;
end process;
end generate;
xm3232 : if MULTIPLIER = m32x32 generate
m0 : hw_smult generic map (33, 33)
port map (clk, holdn, ma(32 downto 0), mb(32 downto 0), prod(65 downto 0));
end generate;
reg : process(clk)
begin
if rising_edge(clk) then
if (holdn = '1') then rm <= rmin; end if;
end if;
end process;
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