microwatt/multiply-32s.vhdl

library ieee;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;

library work;
use work.common.all;

-- Signed 33b x 33b multiplier giving 64-bit product, with no addend,
-- with fixed 1-cycle latency.

entity multiply_32s is
    port (
        clk   : in std_logic;
        stall : in std_ulogic;

        m_in  : in MultiplyInputType;
        m_out : out MultiplyOutputType
        );
end entity multiply_32s;

architecture behaviour of multiply_32s is
    type reg_type is record
        valid     : std_ulogic;
        data      : signed(65 downto 0);
    end record;
    constant reg_type_init : reg_type := (valid => '0', data => (others => '0'));

    signal r, rin : reg_type := reg_type_init;
begin
    multiply_0: process(clk)
    begin
        if rising_edge(clk) and stall = '0' then
            r <= rin;
        end if;
    end process;

    multiply_1: process(all)
        variable v : reg_type;
        variable d : std_ulogic_vector(63 downto 0);
	variable ov : std_ulogic;
    begin
        v.valid := m_in.valid;
        v.data := signed(m_in.data1(32 downto 0)) * signed(m_in.data2(32 downto 0));

        d := std_ulogic_vector(r.data(63 downto 0));

        ov := (or d(63 downto 31)) and not (and d(63 downto 31));

        m_out.result <= 64x"0" & d;
        m_out.overflow <= ov;
        m_out.valid <= r.valid;

        rin <= v;
    end process;
end architecture behaviour;
execute1: Add a pipelined 33-bit signed multiplier This adds a pipelined 33-bit by 33-bit signed multiplier with one cycle latency to the execute pipeline, and uses it for the mullw, mulhw and mulhwu instructions. Because it has one cycle of latency we can assume that its result is available in the second execute stage without needing to add busy logic to the second stage. This adds both a generic version of the multiplier and a Xilinx-specific version using four DSP slices of the Artix-7. Signed-off-by: Paul Mackerras <paulus@ozlabs.org> 2 years ago			`library ieee;`
			`use ieee.std_logic_1164.all;`
			`use ieee.numeric_std.all;`

			`library work;`
			`use work.common.all;`

			`-- Signed 33b x 33b multiplier giving 64-bit product, with no addend,`
			`-- with fixed 1-cycle latency.`

			`entity multiply_32s is`
			`port (`
			`clk : in std_logic;`
			`stall : in std_ulogic;`

			`m_in : in MultiplyInputType;`
			`m_out : out MultiplyOutputType`
			`);`
			`end entity multiply_32s;`

			`architecture behaviour of multiply_32s is`
			`type reg_type is record`
			`valid : std_ulogic;`
			`data : signed(65 downto 0);`
			`end record;`
			`constant reg_type_init : reg_type := (valid => '0', data => (others => '0'));`

			`signal r, rin : reg_type := reg_type_init;`
			`begin`
			`multiply_0: process(clk)`
			`begin`
			`if rising_edge(clk) and stall = '0' then`
			`r <= rin;`
			`end if;`
			`end process;`

			`multiply_1: process(all)`
			`variable v : reg_type;`
			`variable d : std_ulogic_vector(63 downto 0);`
			`variable ov : std_ulogic;`
			`begin`
			`v.valid := m_in.valid;`
			`v.data := signed(m_in.data1(32 downto 0)) * signed(m_in.data2(32 downto 0));`

			`d := std_ulogic_vector(r.data(63 downto 0));`

			`ov := (or d(63 downto 31)) and not (and d(63 downto 31));`

			`m_out.result <= 64x"0" & d;`
			`m_out.overflow <= ov;`
			`m_out.valid <= r.valid;`

			`rin <= v;`
			`end process;`
			`end architecture behaviour;`