pluto_hdl_adi/library/util_axis_fifo/util_axis_fifo.v

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// ***************************************************************************
// ***************************************************************************
// Copyright 2014 - 2017 (c) Analog Devices, Inc. All rights reserved.
//
// In this HDL repository, there are many different and unique modules, consisting
// of various HDL (Verilog or VHDL) components. The individual modules are
// developed independently, and may be accompanied by separate and unique license
// terms.
//
// The user should read each of these license terms, and understand the
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// freedoms and responsibilities that he or she has by using this source/core.
//
// This core 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.
//
// Redistribution and use of source or resulting binaries, with or without modification
// of this file, are permitted under one of the following two license terms:
//
// 1. The GNU General Public License version 2 as published by the
// Free Software Foundation, which can be found in the top level directory
// of this repository (LICENSE_GPL2), and also online at:
// <https://www.gnu.org/licenses/old-licenses/gpl-2.0.html>
//
// OR
//
// 2. An ADI specific BSD license, which can be found in the top level directory
// of this repository (LICENSE_ADIBSD), and also on-line at:
// https://github.com/analogdevicesinc/hdl/blob/master/LICENSE_ADIBSD
// This will allow to generate bit files and not release the source code,
// as long as it attaches to an ADI device.
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//
// ***************************************************************************
// ***************************************************************************
`timescale 1ns/100ps
module util_axis_fifo #(
parameter DATA_WIDTH = 64,
parameter ASYNC_CLK = 1,
parameter ADDRESS_WIDTH = 4,
parameter S_AXIS_REGISTERED = 1
) (
input m_axis_aclk,
input m_axis_aresetn,
input m_axis_ready,
output m_axis_valid,
output [DATA_WIDTH-1:0] m_axis_data,
output [ADDRESS_WIDTH:0] m_axis_level,
input s_axis_aclk,
input s_axis_aresetn,
output s_axis_ready,
input s_axis_valid,
input [DATA_WIDTH-1:0] s_axis_data,
output s_axis_empty,
output [ADDRESS_WIDTH:0] s_axis_room
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);
hdl/library: Update the IP parameters The following IP parameters were renamed: PCORE_ID --> ID PCORE_DEVTYPE --> DEVICE_TYPE PCORE_IODELAY_GROUP --> IO_DELAY_GROUP CH_DW --> CHANNEL_DATA_WIDTH CH_CNT --> NUM_OF_CHANNELS PCORE_BUFTYPE --> DEVICE_TYPE PCORE_ADC_DP_DISABLE --> ADC_DATAPATH_DISABLE CHID --> CHANNEL_ID PCORE_DEVICE_TYPE --> DEVICE_TYPE PCORE_MMCM_BUFIO_N --> MMCM_BUFIO_N PCORE_SERDES_DDR_N --> SERDES_DDR_N PCORE_DAC_DP_DISABLE --> DAC_DATAPATH_DISABLE DP_DISABLE --> DATAPATH_DISABLE PCORE_DAC_IODELAY_ENABLE --> DAC_IODELAY_ENABLE C_BIG_ENDIAN --> BIG_ENDIAN C_M_DATA_WIDTH --> MASTER_DATA_WIDTH C_S_DATA_WIDTH --> SLAVE_DATA_WIDTH NUM_CHANNELS --> NUM_OF_CHANNELS CHANNELS --> NUM_OF_CHANNELS PCORE_4L_2L_N -->QUAD_OR_DUAL_N C_ADDRESS_WIDTH --> ADDRESS_WIDTH C_DATA_WIDTH --> DATA_WIDTH C_CLKS_ASYNC --> CLKS_ASYNC PCORE_QUAD_DUAL_N --> QUAD_DUAL_N NUM_CS --> NUM_OF_CS PCORE_DAC_CHANNEL_ID --> DAC_CHANNEL_ID PCORE_ADC_CHANNEL_ID --> ADC_CHANNEL_ID PCORE_CLK0_DIV --> CLK0_DIV PCORE_CLK1_DIV --> CLK1_DIV PCORE_CLKIN_PERIOD --> CLKIN_PERIOD PCORE_VCO_DIV --> VCO_DIV PCORE_Cr_Cb_N --> CR_CB_N PCORE_VCO_MUL --> VCO_MUL PCORE_EMBEDDED_SYNC --> EMBEDDED_SYNC PCORE_AXI_ID_WIDTH --> AXI_ID_WIDTH PCORE_ADDR_WIDTH --> ADDRESS_WIDTH DADATA_WIDTH --> DATA_WIDTH NUM_OF_NUM_OF_CHANNEL --> NUM_OF_CHANNELS DEBOUNCER_LEN --> DEBOUNCER_LENGTH ADDR_WIDTH --> ADDRESS_WIDTH C_S_AXIS_REGISTERED --> S_AXIS_REGISTERED Cr_Cb_N --> CR_CB_N ADDATA_WIDTH --> ADC_DATA_WIDTH BUFTYPE --> DEVICE_TYPE NUM_BITS --> NUM_OF_BITS WIDTH_A --> A_DATA_WIDTH WIDTH_B --> B_DATA_WIDTH CH_OCNT --> NUM_OF_CHANNELS_O M_CNT --> NUM_OF_CHANNELS_M P_CNT --> NUM_OF_CHANNELS_P CH_ICNT --> NUM_OF_CHANNELS_I CH_MCNT --> NUM_OF_CHANNELS_M 4L_2L_N --> QUAD_OR_DUAL_N SPI_CLK_ASYNC --> ASYNC_SPI_CLK MMCM_BUFIO_N --> MMCM_OR_BUFIO_N SERDES_DDR_N --> SERDES_OR_DDR_N CLK_ASYNC --> ASYNC_CLK CLKS_ASYNC --> ASYNC_CLK SERDES --> SERDES_OR_DDR_N GTH_GTX_N --> GTH_OR_GTX_N IF_TYPE --> DDR_OR_SDR_N PARALLEL_WIDTH --> DATA_WIDTH ADD_SUB --> ADD_OR_SUB_N A_WIDTH --> A_DATA_WIDTH CONST_VALUE --> B_DATA_VALUE IO_BASEADDR --> BASE_ADDRESS IO_WIDTH --> DATA_WIDTH QUAD_DUAL_N --> QUAD_OR_DUAL_N AXI_ADDRLIMIT --> AXI_ADDRESS_LIMIT ADDRESS_A_DATA_WIDTH --> A_ADDRESS_WIDTH ADDRESS_B_DATA_WIDTH --> B_ADDRESS_WIDTH MODE_OF_ENABLE --> CONTROL_TYPE CONTROL_TYPE --> LEVEL_OR_PULSE_N IQSEL --> Q_OR_I_N MMCM --> MMCM_OR_BUFR_N
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generate if (ADDRESS_WIDTH == 0) begin
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reg [DATA_WIDTH-1:0] cdc_sync_fifo_ram;
reg s_axis_waddr = 1'b0;
reg m_axis_raddr = 1'b0;
wire m_axis_waddr;
wire s_axis_raddr;
sync_bits #(
.NUM_OF_BITS(1),
.ASYNC_CLK(ASYNC_CLK)
) i_waddr_sync (
.out_clk(m_axis_aclk),
.out_resetn(m_axis_aresetn),
.in(s_axis_waddr),
.out(m_axis_waddr)
);
sync_bits #(
.NUM_OF_BITS(1),
.ASYNC_CLK(ASYNC_CLK)
) i_raddr_sync (
.out_clk(s_axis_aclk),
.out_resetn(s_axis_aresetn),
.in(m_axis_raddr),
.out(s_axis_raddr)
);
assign m_axis_valid = m_axis_raddr != m_axis_waddr;
assign m_axis_level = m_axis_valid;
assign s_axis_ready = s_axis_raddr == s_axis_waddr;
assign s_axis_empty = s_axis_ready;
assign s_axis_room = s_axis_ready;
always @(posedge s_axis_aclk) begin
if (s_axis_ready == 1'b1 && s_axis_valid == 1'b1)
cdc_sync_fifo_ram <= s_axis_data;
end
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always @(posedge s_axis_aclk) begin
if (s_axis_aresetn == 1'b0) begin
s_axis_waddr <= 1'b0;
end else begin
if (s_axis_ready & s_axis_valid) begin
s_axis_waddr <= s_axis_waddr + 1'b1;
end
end
end
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always @(posedge m_axis_aclk) begin
if (m_axis_aresetn == 1'b0) begin
m_axis_raddr <= 1'b0;
end else begin
if (m_axis_valid & m_axis_ready)
m_axis_raddr <= m_axis_raddr + 1'b1;
end
end
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assign m_axis_data = cdc_sync_fifo_ram;
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end else begin
reg [DATA_WIDTH-1:0] ram[0:2**ADDRESS_WIDTH-1];
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wire [ADDRESS_WIDTH-1:0] s_axis_waddr;
wire [ADDRESS_WIDTH-1:0] m_axis_raddr;
wire _m_axis_ready;
wire _m_axis_valid;
wire [ADDRESS_WIDTH:0] _m_axis_level;
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wire s_mem_write;
wire m_mem_read;
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reg valid;
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always @(posedge m_axis_aclk) begin
if (m_axis_aresetn == 1'b0) begin
valid <= 1'b0;
end else begin
if (_m_axis_valid)
valid <= 1'b1;
else if (m_axis_ready)
valid <= 1'b0;
end
end
assign s_mem_write = s_axis_ready & s_axis_valid;
assign m_mem_read = (~valid || m_axis_ready) && _m_axis_valid;
if (ASYNC_CLK == 1) begin
// The assumption is that in this mode the S_AXIS_REGISTERED is 1
fifo_address_gray_pipelined #(
.ADDRESS_WIDTH(ADDRESS_WIDTH)
) i_address_gray (
.m_axis_aclk(m_axis_aclk),
.m_axis_aresetn(m_axis_aresetn),
.m_axis_ready(_m_axis_ready),
.m_axis_valid(_m_axis_valid),
.m_axis_raddr(m_axis_raddr),
.m_axis_level(_m_axis_level),
.s_axis_aclk(s_axis_aclk),
.s_axis_aresetn(s_axis_aresetn),
.s_axis_ready(s_axis_ready),
.s_axis_valid(s_axis_valid),
.s_axis_empty(s_axis_empty),
.s_axis_waddr(s_axis_waddr),
.s_axis_room(s_axis_room)
);
// When the clocks are asynchronous instantiate a block RAM
// regardless of the requested size to make sure we threat the
// clock crossing correctly
ad_mem #(
.DATA_WIDTH (DATA_WIDTH),
.ADDRESS_WIDTH (ADDRESS_WIDTH))
i_mem (
.clka(s_axis_aclk),
.wea(s_mem_write),
.addra(s_axis_waddr),
.dina(s_axis_data),
.clkb(m_axis_aclk),
.reb(m_mem_read),
.addrb(m_axis_raddr),
.doutb(m_axis_data)
);
assign _m_axis_ready = ~valid || m_axis_ready;
assign m_axis_valid = valid;
// the util_axis_fifo is functioning in 'first write fall through' mode,
// which means that we need to assure that the value of the level reflects
// the actual FIFO level plus the available data, which sits on the bus
assign m_axis_level = (m_axis_valid) ? _m_axis_level + 1'b1 : _m_axis_level;
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end else begin
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fifo_address_sync #(
.ADDRESS_WIDTH(ADDRESS_WIDTH)
) i_address_sync (
.clk(m_axis_aclk),
.resetn(m_axis_aresetn),
.m_axis_ready(_m_axis_ready),
.m_axis_valid(_m_axis_valid),
.m_axis_raddr(m_axis_raddr),
.m_axis_level(m_axis_level),
.s_axis_ready(s_axis_ready),
.s_axis_valid(s_axis_valid),
.s_axis_empty(s_axis_empty),
.s_axis_waddr(s_axis_waddr),
.s_axis_room(s_axis_room)
);
// When the clocks are synchronous use behavioral modeling for the SDP RAM
// Let the synthesizer decide what to infer (distributed or block RAM)
always @(posedge s_axis_aclk) begin
if (s_mem_write)
ram[s_axis_waddr] <= s_axis_data;
end
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if (S_AXIS_REGISTERED == 1) begin
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reg [DATA_WIDTH-1:0] data;
always @(posedge m_axis_aclk) begin
if (m_mem_read)
data <= ram[m_axis_raddr];
end
assign _m_axis_ready = ~valid || m_axis_ready;
assign m_axis_data = data;
assign m_axis_valid = valid;
end else begin
assign _m_axis_ready = m_axis_ready;
assign m_axis_valid = _m_axis_valid;
assign m_axis_data = ram[m_axis_raddr];
end
end
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end endgenerate
endmodule