common/ad_upack: Generic unpacker core and testbench

Unpacker:
   - unpack O_W number of data units from I_W number of data units
   - data unit defined in bits by UNIT_W e.g 8 is a byte

library/common/ad_upack.v

@@ -0,0 +1,168 @@
+// ***************************************************************************
+// ***************************************************************************
+// Copyright 2014 - 2020 (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
+// 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.
+//
+// ***************************************************************************
+// ***************************************************************************
+
+`timescale 1ns/100ps
+
+// Unpacker:
+//   - unpack O_W number of data units from I_W number of data units
+//   - data unit defined in bits by UNIT_W e.g 8 is a byte
+//
+// Constraints:
+//   - O_W <= I_W
+//   - LATENCY 1 
+//   - no backpressure
+//
+// Data format:
+//  idata  [U(I_W-1) .... U(0)]
+//  odata  [U(O_W-1) .... U(0)]
+//
+// e.g
+//  I_W = 6
+//  O_W = 4
+//  UNIT_W = 8
+//
+//  idata : [B5,B4,B3,B2,B1,B0],[B11,B10,B9,B8,B7,B6]
+//  odata :                     [B3,B2,B1,B0],[B7,B6,B5,B4],[B11,B10,B9,B8]
+//
+
+module ad_upack #(
+  parameter I_W = 4,
+  parameter O_W = 3,
+  parameter UNIT_W = 8,
+  parameter O_REG = 1
+) (
+  input                   clk,
+  input                   reset,
+  input [I_W*UNIT_W-1:0]  idata,
+  input                   ivalid,
+  output                  iready,
+
+  output reg [O_W*UNIT_W-1:0] odata = 'h0,
+  output reg                  ovalid = 'b0
+);
+
+// Width of shift reg is integer multiple of output data width
+localparam SH_W = ((I_W/O_W)+1)*O_W;
+localparam STEP = I_W % O_W;
+
+localparam LATENCY = 1; // Minimum input latency from iready to ivalid 
+
+integer i;
+
+reg [SH_W*UNIT_W-1:0] idata_sh;
+reg [SH_W*UNIT_W-1:0] idata_d = 'h0;
+reg [SH_W*UNIT_W-1:0] idata_d_nx;
+reg [SH_W-1:0] in_use = 'h0;
+reg [SH_W-1:0] inmask;
+
+wire [SH_W-1:0] out_mask = {O_W{1'b1}};
+wire [SH_W-1:0] in_use_nx;
+wire [SH_W-1:0] unit_valid;
+wire [O_W*UNIT_W-1:0] odata_s;
+wire                  ovalid_s;
+
+assign unit_valid = (in_use | inmask);
+assign in_use_nx = unit_valid >> O_W;
+
+always @(posedge clk) begin
+  if (reset) begin
+    in_use <= 'h0;
+  end else if (ovalid_s) begin
+    in_use <= in_use_nx;
+  end
+end
+
+always @(*) begin
+  inmask = {I_W{ivalid}};
+  if (STEP>0) begin
+    for (i = STEP; i < O_W; i=i+STEP) begin
+      if (in_use[i-1]) begin
+        inmask = {I_W{ivalid}} << i;
+      end
+    end
+  end
+end
+
+always @(*) begin
+  idata_d_nx = idata_d;
+  if (ivalid) begin
+    idata_d_nx = {{(SH_W-I_W)*UNIT_W{1'b0}},idata};
+    if (STEP>0) begin
+      for (i = STEP; i < O_W; i=i+STEP) begin
+        if (in_use[i-1]) begin
+          idata_d_nx = (idata << UNIT_W*i) | idata_d;
+        end
+      end
+    end
+  end
+end
+
+always @(posedge clk) begin
+  if (ovalid_s) begin
+    idata_d <= idata_d_nx >> O_W*UNIT_W;
+  end
+end
+
+assign iready = ~unit_valid[LATENCY*O_W + O_W -1];
+
+assign odata_s = idata_d_nx[O_W*UNIT_W-1:0];
+assign ovalid_s = unit_valid[O_W-1];
+
+generate
+  if (O_REG) begin : o_reg
+
+    always @(posedge clk) begin
+      if (reset) begin
+        ovalid <= 1'b0;
+      end else begin
+        ovalid <= ovalid_s;
+      end
+    end
+
+    always @(posedge clk) begin
+      odata <= odata_s;
+    end
+
+  end else begin
+
+    always @(*) begin
+      odata = odata_s;
+      ovalid = ovalid_s;
+    end
+
+  end
+endgenerate
+
+endmodule

library/common/tb/ad_upack_tb

@@ -0,0 +1,7 @@
+#!/bin/bash
+
+SOURCE="ad_upack_tb.v"
+SOURCE+=" ../ad_upack.v"
+
+cd `dirname $0`
+source run_tb.sh

library/common/tb/ad_upack_tb.v

@@ -0,0 +1,111 @@
+`timescale 1ns/100ps
+
+module ad_upack_tb;
+  parameter VCD_FILE = "ad_upack_tb.vcd";
+
+  parameter I_W = 6;   // Width of input channel
+  parameter O_W = 4;   // Width of output channel
+  parameter UNIT_W = 8;
+  parameter VECT_W = 1024*8;  // Multiple of 8
+
+  `include "tb_base.v"
+
+  reg [I_W*UNIT_W-1 : 0]  idata;
+  wire [O_W*UNIT_W-1 : 0] odata;
+  reg                     ivalid = 'b0;
+  reg [VECT_W-1:0] input_vector;
+  reg [VECT_W-1:0] output_vector;
+
+  integer i=0;
+  integer j=0;
+
+  ad_upack #(
+    .I_W(I_W),
+    .O_W(O_W),
+    .UNIT_W(UNIT_W)
+  ) DUT (
+    .clk(clk),
+    .reset(reset),
+    .idata(idata),
+    .iready(iready),
+    .ivalid(ivalid),
+    .odata(odata),
+    .ovalid(ovalid)
+  );
+
+  task test(input no_random);
+  begin
+    @(posedge clk);
+    i = 0;
+    j = 0;
+    while (i < VECT_W/(I_W*UNIT_W)) begin
+      @(posedge clk);
+      if (iready & (($urandom % 2 == 0) | no_random)) begin
+        idata <= input_vector[i*(I_W*UNIT_W) +: (I_W*UNIT_W)];
+        ivalid <= 1'b1;
+        i = i + 1;
+      end else begin
+        idata <= 'bx;
+        ivalid <= 1'b0;
+      end
+    end
+    @(posedge clk);
+    idata <= 'bx;
+    ivalid <= 1'b0;
+
+    // Check output vector
+    repeat (20) @(posedge clk);
+    for (i=0; i<(((VECT_W/(I_W*UNIT_W))*(I_W*UNIT_W))/(O_W*UNIT_W))*(O_W*UNIT_W)/8; i=i+1) begin
+      if (input_vector[i*8+:8] !== output_vector[i*8+:8]) begin
+        failed <= 1'b1;
+        $display("i=%d Expected=%x Found=%x",i,input_vector[i*8+:8],output_vector[i*8+:8]);
+      end
+    end
+  end
+  endtask
+
+  initial begin
+
+    @(negedge reset);
+
+    // Test with incremental data
+    for (i=0; i<VECT_W/8; i=i+1) begin
+      input_vector[i*8+:8] = i[7:0];
+      output_vector[i*8+:8] = 'bx;
+    end
+
+    test(1);
+
+    do_trigger_reset();
+    @(negedge reset);
+
+    // Test with incremental data random timing
+    for (i=0; i<VECT_W/8; i=i+1) begin
+      input_vector[i*8+:8] = i[7:0];
+      output_vector[i*8+:8] = 'bx;
+    end
+
+    test(0);
+
+    do_trigger_reset();
+    @(negedge reset);
+
+    // Test with randomized data random timing
+    for (i=0; i<VECT_W/8; i=i+1) begin
+      input_vector[i*8+:8] = $urandom;
+    end
+
+    test(0);
+
+  end
+
+  always @(posedge clk) begin
+    if (ovalid) begin
+      if (j < VECT_W/(O_W*UNIT_W)) begin
+        output_vector[j*(O_W*UNIT_W) +: (O_W*UNIT_W)] = odata;
+        j = j + 1;
+      end
+    end
+  end
+
+endmodule