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generic_async_fifo.vhd
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--------------------------------------------------------------------------------
-- CERN BE-CO-HT
-- General Cores Library
-- https://www.ohwr.org/projects/general-cores
--------------------------------------------------------------------------------
--
-- unit name: generic_async_fifo
--
-- description: Parametrizable asynchronous FIFO (Generic version).
-- Dual-clock asynchronous FIFO.
-- - configurable data width and size
-- - configurable full/empty/almost full/almost empty/word count signals
--
--------------------------------------------------------------------------------
-- Copyright CERN 2011-2018
--------------------------------------------------------------------------------
-- Copyright and related rights are licensed under the Solderpad Hardware
-- License, Version 2.0 (the "License"); you may not use this file except
-- in compliance with the License. You may obtain a copy of the License at
-- http://solderpad.org/licenses/SHL-2.0.
-- Unless required by applicable law or agreed to in writing, software,
-- hardware and materials distributed under this License is distributed on an
-- "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express
-- or implied. See the License for the specific language governing permissions
-- and limitations under the License.
--------------------------------------------------------------------------------
library ieee;
use ieee.std_logic_1164.all;
use ieee.numeric_std.all;
use work.genram_pkg.all;
entity generic_async_fifo is
generic (
g_data_width : natural;
g_size : natural;
g_show_ahead : boolean := false;
-- Read-side flag selection
g_with_rd_empty : boolean := true; -- with empty flag
g_with_rd_full : boolean := false; -- with full flag
g_with_rd_almost_empty : boolean := false;
g_with_rd_almost_full : boolean := false;
g_with_rd_count : boolean := false; -- with words counter
g_with_wr_empty : boolean := false;
g_with_wr_full : boolean := true;
g_with_wr_almost_empty : boolean := false;
g_with_wr_almost_full : boolean := false;
g_with_wr_count : boolean := false;
g_almost_empty_threshold : integer; -- threshold for almost empty flag
g_almost_full_threshold : integer -- threshold for almost full flag
);
port (
rst_n_i : in std_logic := '1';
-- write port
clk_wr_i : in std_logic;
d_i : in std_logic_vector(g_data_width-1 downto 0);
we_i : in std_logic;
wr_empty_o : out std_logic;
wr_full_o : out std_logic;
wr_almost_empty_o : out std_logic;
wr_almost_full_o : out std_logic;
wr_count_o : out std_logic_vector(f_log2_size(g_size)-1 downto 0);
-- read port
clk_rd_i : in std_logic;
q_o : out std_logic_vector(g_data_width-1 downto 0);
rd_i : in std_logic;
rd_empty_o : out std_logic;
rd_full_o : out std_logic;
rd_almost_empty_o : out std_logic;
rd_almost_full_o : out std_logic;
rd_count_o : out std_logic_vector(f_log2_size(g_size)-1 downto 0)
);
end generic_async_fifo;
architecture syn of generic_async_fifo is
component inferred_async_fifo
generic (
g_data_width : natural;
g_size : natural;
g_show_ahead : boolean;
g_with_rd_empty : boolean;
g_with_rd_full : boolean;
g_with_rd_almost_empty : boolean;
g_with_rd_almost_full : boolean;
g_with_rd_count : boolean;
g_with_wr_empty : boolean;
g_with_wr_full : boolean;
g_with_wr_almost_empty : boolean;
g_with_wr_almost_full : boolean;
g_with_wr_count : boolean;
g_almost_empty_threshold : integer;
g_almost_full_threshold : integer);
port (
rst_n_i : in std_logic := '1';
clk_wr_i : in std_logic;
d_i : in std_logic_vector(g_data_width-1 downto 0);
we_i : in std_logic;
wr_empty_o : out std_logic;
wr_full_o : out std_logic;
wr_almost_empty_o : out std_logic;
wr_almost_full_o : out std_logic;
wr_count_o : out std_logic_vector(f_log2_size(g_size)-1 downto 0);
clk_rd_i : in std_logic;
q_o : out std_logic_vector(g_data_width-1 downto 0);
rd_i : in std_logic;
rd_empty_o : out std_logic;
rd_full_o : out std_logic;
rd_almost_empty_o : out std_logic;
rd_almost_full_o : out std_logic;
rd_count_o : out std_logic_vector(f_log2_size(g_size)-1 downto 0));
end component;
begin -- syn
U_Inferred_FIFO : inferred_async_fifo
generic map (
g_data_width => g_data_width,
g_size => g_size,
g_show_ahead => g_show_ahead,
g_with_rd_empty => g_with_rd_empty,
g_with_rd_full => g_with_rd_full,
g_with_rd_almost_empty => g_with_rd_almost_empty,
g_with_rd_almost_full => g_with_rd_almost_full,
g_with_rd_count => g_with_rd_count,
g_with_wr_empty => g_with_wr_empty,
g_with_wr_full => g_with_wr_full,
g_with_wr_almost_empty => g_with_wr_almost_empty,
g_with_wr_almost_full => g_with_wr_almost_full,
g_with_wr_count => g_with_wr_count,
g_almost_empty_threshold => g_almost_empty_threshold,
g_almost_full_threshold => g_almost_full_threshold)
port map (
rst_n_i => rst_n_i,
clk_wr_i => clk_wr_i,
d_i => d_i,
we_i => we_i,
wr_empty_o => wr_empty_o,
wr_full_o => wr_full_o,
wr_almost_empty_o => wr_almost_empty_o,
wr_almost_full_o => wr_almost_full_o,
wr_count_o => wr_count_o,
clk_rd_i => clk_rd_i,
q_o => q_o,
rd_i => rd_i,
rd_empty_o => rd_empty_o,
rd_full_o => rd_full_o,
rd_almost_empty_o => rd_almost_empty_o,
rd_almost_full_o => rd_almost_full_o,
rd_count_o => rd_count_o);
end syn;