//======================================================================
//
// tb_keywrap.v
// ------------
// Testbench for the keywrap top level wrapper (and core).
//
//
// Author: Joachim Strombergson
// Copyright (c) 2018, NORDUnet A/S
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
// - Redistributions of source code must retain the above copyright notice,
// this list of conditions and the following disclaimer.
//
// - Redistributions in binary form must reproduce the above copyright
// notice, this list of conditions and the following disclaimer in the
// documentation and/or other materials provided with the distribution.
//
// - Neither the name of the NORDUnet nor the names of its contributors may
// be used to endorse or promote products derived from this software
// without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
// TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//
//======================================================================
module tb_keywrap();
parameter DEBUG = 0;
parameter DUMP_TOP = 0;
parameter DUMP_CORE = 0;
parameter CLK_HALF_PERIOD = 1;
parameter CLK_PERIOD = 2 * CLK_HALF_PERIOD;
parameter ADDR_BITS = 13;
parameter MEM_BASE = {1'h1, {(ADDR_BITS - 1){1'h0}}};
// API for the core.
localparam ADDR_NAME0 = 8'h00;
localparam ADDR_NAME1 = 8'h01;
localparam ADDR_VERSION = 8'h02;
localparam ADDR_CTRL = 8'h08;
localparam CTRL_INIT_BIT = 0;
localparam CTRL_NEXT_BIT = 1;
localparam ADDR_STATUS = 8'h09;
localparam STATUS_READY_BIT = 0;
localparam STATUS_VALID_BIT = 1;
localparam ADDR_CONFIG = 8'h0a;
localparam CTRL_ENCDEC_BIT = 0;
localparam CTRL_KEYLEN_BIT = 1;
localparam ADDR_RLEN = 8'h0c;
localparam ADDR_R_BANK = 8'h0d;
localparam ADDR_A0 = 8'h0e;
localparam ADDR_A1 = 8'h0f;
localparam ADDR_KEY0 = 8'h10;
localparam ADDR_KEY1 = 8'h11;
localparam ADDR_KEY2 = 8'h12;
localparam ADDR_KEY3 = 8'h13;
localparam ADDR_KEY4 = 8'h14;
localparam ADDR_KEY5 = 8'h15;
localparam ADDR_KEY6 = 8'h16;
localparam ADDR_KEY7 = 8'h17;
localparam ADDR_R_DATA0 = 8'h80;
localparam ADDR_R_DATA127 = 8'hff;
//----------------------------------------------------------------
// Register and Wire declarations.
//----------------------------------------------------------------
reg [31 : 0] cycle_ctr;
reg [31 : 0] error_ctr;
reg [31 : 0] tc_ctr;
reg [31 : 0] read_data;
reg [127 : 0] result_data;
reg tb_clk;
reg tb_reset_n;
reg tb_cs;
reg tb_we;
reg [(ADDR_BITS -1 ) : 0] tb_address;
reg [31 : 0] tb_write_data;
wire [31 : 0] tb_read_data;
wire tb_error;
//----------------------------------------------------------------
// Device Under Test.
//----------------------------------------------------------------
keywrap dut(
.clk(tb_clk),
.reset_n(tb_reset_n),
.cs(tb_cs),
.we(tb_we),
.address(tb_address),
.write_data(tb_write_data),
.read_data(tb_read_data),
.error(tb_error)
);
//----------------------------------------------------------------
// clk_gen
//
// Always running clock generator process.
//----------------------------------------------------------------
always
begin : clk_gen
#CLK_HALF_PERIOD;
tb_clk = !tb_clk;
end // clk_gen
//----------------------------------------------------------------
// sys_monitor()
//
// An always running process that creates a cycle counter and
// conditionally displays information about the DUT.
//----------------------------------------------------------------
always
begin : sys_monitor
cycle_ctr = cycle_ctr + 1;
if (DEBUG)
dump_dut_state();
#(CLK_PERIOD);
end
//----------------------------------------------------------------
// read_word()
//
// Read a data word from the given address in the DUT.
// the word read will be available in the global variable
// read_data.
//----------------------------------------------------------------
task read_word(input [11 : 0] address);
begin
tb_address = address;
tb_cs = 1;
tb_we = 0;
#(CLK_PERIOD);
read_data = tb_read_data;
tb_cs = 0;
if (DEBUG)
begin
$display("*** Reading 0x%08x from 0x%02x.", read_data, address);
$display("");
end
end
endtask // read_word
//----------------------------------------------------------------
// write_word()
//
// Write the given word to the DUT using the DUT interface.
//----------------------------------------------------------------
task write_word(input [11 : 0] address,
input [31 : 0] word);
begin
if (DEBUG)
begin
$display("*** Writing 0x%08x to 0x%02x.", word, address);
$display("");
end
tb_address = address;
tb_write_data = word;
tb_cs = 1;
tb_we = 1;
#(1 * CLK_PERIOD);
tb_cs = 0;
tb_we = 0;
end
endtask // write_word
//----------------------------------------------------------------
// wait_ready
//
// Wait for the DUT to signal that the result is ready
//----------------------------------------------------------------
task wait_ready;
begin : wait_ready
reg rdy;
rdy = 1'b0;
while (rdy != 1'b1)
begin
read_word(ADDR_STATUS);
rdy = tb_read_data[STATUS_READY_BIT];
end
end
endtask // wait_ready
//----------------------------------------------------------------
// dump_mem()
//
// Dump the n first memory positions in the dut internal memory.
//----------------------------------------------------------------
task dump_mem(input integer n);
begin : dump_mem
integer i;
for (i = 0 ; i < n ; i = i + 1)
$display("mem0[0x%06x] = 0x%08x mem1[0x%06x] = 0x%08x",
i, dut.core.mem.mem0[i], i, dut.core.mem.mem1[i]);
$display("");
end
endtask // dump_mem
//----------------------------------------------------------------
// dump_dut_state()
//
// Dump the state of the dump when needed.
//----------------------------------------------------------------
task dump_dut_state;
begin
$display("cycle: 0x%016x", cycle_ctr);
$display("State of DUT");
$display("------------");
if (DUMP_TOP)
begin
$display("top level state:");
$display("init_reg = 0x%x next_reg = 0x%x", dut.init_reg, dut.next_reg);
$display("endec_reg = 0x%x keylen_reg = 0x%x", dut.encdec_reg, dut.keylen_reg);
$display("rlen_reg = 0x%08x", dut.rlen_reg);
$display("a0_reg = 0x%08x a1_reg = 0x%08x", dut.a0_reg, dut.a1_reg);
$display("");
end
if (DUMP_CORE)
begin
$display("core level state:");
$display("init = 0x%0x next = 0x%0x ready = 0x%0x valid = 0x%0x",
dut.core.init, dut.core.next, dut.core.ready, dut.core.valid);
$display("api_we = 0x%0x api_addr = 0x%0x api_wr_data = 0x%0x api_rd_data = 0x%0x",
dut.core.api_we, dut.core.api_addr, dut.core.api_wr_data, dut.core.api_rd_data);
$display("rlen = 0x%0x", dut.core.rlen);
$display("key = 0x%0x", dut.core.key);
$display("a_init = 0x%0x a_result = 0x%0x", dut.core.a_init, dut.core.a_result);
$display("");
$display("update_state = 0x%0x", dut.core.update_state);
$display("a_reg = 0x%0x a_new = 0x%0x a_we = 0x%0x",
dut.core.a_reg, dut.core.a_new, dut.core.a_we);
$display("core_we = 0x%0x core_addr = 0x%0x",
dut.core.core_we, dut.core.core_addr);
$display("core_rd_data = 0x%0x core_wr_data = 0x%0x ",
dut.core.core_rd_data, dut.core.core_wr_data);
$display("xor_val = 0x%0x", dut.core.keywrap_logic.xor_val);
$display("");
$display("aes_ready = 0x%0x aes_valid = 0x%0x",
dut.core.aes_ready, dut.core.aes_valid);
$display("aes_init = 0x%0x aes_next = 0x%0x",
dut.core.aes_init, dut.core.aes_next);
$display("aes_block = 0x%0x aes_result = 0x%0x",
dut.core.aes_block, dut.core.aes_result);
$display("");
$display("block_ctr_reg = 0x%0x iteration_ctr_reg = 0x%0x",
dut.core.block_ctr_reg, dut.core.iteration_ctr_reg);
$display("keywrap_core_ctrl_reg = 0x%0x", dut.core.keywrap_core_ctrl_reg);
$display("keywrap_core_ctrl_new = 0x%0x", dut.core.keywrap_core_ctrl_new);
$display("keywrap_core_ctrl_we = 0x%0x", dut.core.keywrap_core_ctrl_we);
end
$display("");
$display("");
end
endtask // dump_dut_state
//----------------------------------------------------------------
// display_test_results()
//
// Display the accumulated test results.
//----------------------------------------------------------------
task display_test_results;
begin
if (error_ctr == 0)
begin
$display("*** All %02d test cases completed successfully", tc_ctr);
end
else
begin
$display("*** %02d tests completed - %02d test cases did not complete successfully.",
tc_ctr, error_ctr);
end
end
endtask // display_test_results
//----------------------------------------------------------------
// init_sim()
//
// Initialize all counters and testbed functionality as well
// as setting the DUT inputs to defined values.
//----------------------------------------------------------------
task init_sim;
begin
cycle_ctr = 0;
error_ctr = 0;
tc_ctr = 0;
tb_clk = 0;
tb_reset_n = 1;
tb_cs = 0;
tb_we = 0;
tb_address = 8'h0;
tb_write_data = 32'h0;
end
endtask // init_sim
//----------------------------------------------------------------
// reset_dut()
//
// Toggle reset to put the DUT into a well known state.
//----------------------------------------------------------------
task reset_dut;
begin
$display("** Toggling reset.");
tb_reset_n = 0;
#(2 * CLK_PERIOD);
tb_reset_n = 1;
$display("");
end
endtask // reset_dut
//----------------------------------------------------------------
// test_core_access
// Simple test that we can perform read access to regs
// in the core.
//----------------------------------------------------------------
task test_core_access;
begin : test_core_access
$display("** TC test_core_access START.");
read_word(ADDR_NAME0);
$display("NAME0: %s", read_data);
read_word(ADDR_NAME1);
$display("NAME1: %s", read_data);
read_word(ADDR_VERSION);
$display("version: %s", read_data);
$display("");
$display("** TC test_core_access END.");
end
endtask // test_core_access
//----------------------------------------------------------------
// test_kwp_ae_128_1
// Implements wrap test based on NIST KWP_AE 128 bit key
// with 248 bit plaintext.
//----------------------------------------------------------------
task test_kwp_ae_128_1;
begin : kwp_ae_128_1
integer i;
tc_ctr = tc_ctr + 1;
$display("** TC kwp_ae_128_1 START.");
// Write key and keylength, we also want to encrypt/wrap.
write_word(ADDR_KEY0, 32'hc03db3cc);
write_word(ADDR_KEY1, 32'h1416dcd1);
write_word(ADDR_KEY2, 32'hc069a195);
write_word(ADDR_KEY3, 32'ha8d77e3d);
write_word(ADDR_CONFIG, 32'h00000001);
// Initialize the AES engine (to expand the key).
// Wait for init to complete.
// Note, not actually needed to wait. We can write R data during init.
$display("* Trying to initialize.");
write_word(ADDR_CTRL, 32'h00000001);
#(2 * CLK_PERIOD);
wait_ready();
$display("* Init should be done.");
// Set the length or R in blocks.
// Write the R bank to be written to.
// Write the R blocks to be processed.
write_word(ADDR_RLEN, 32'h00000004);
write_word(MEM_BASE + 0, 32'h46f87f58);
write_word(MEM_BASE + 1, 32'hcdda4200);
write_word(MEM_BASE + 2, 32'hf53d99ce);
write_word(MEM_BASE + 3, 32'h2e49bdb7);
write_word(MEM_BASE + 4, 32'h6212511f);
write_word(MEM_BASE + 5, 32'he0cd4d0b);
write_word(MEM_BASE + 6, 32'h5f37a27d);
write_word(MEM_BASE + 7, 32'h45a28800);
// Write magic words to A.
write_word(ADDR_A0, 32'ha65959a6);
write_word(ADDR_A1, 32'h0000001f);
$display("* Contents of memory and dut before wrap processing:");
dump_mem(6);
// Start wrapping and wait for wrap to complete.
$display("* Trying to start processing.");
write_word(ADDR_CTRL, 32'h00000002);
#(2 * CLK_PERIOD);
wait_ready();
$display("* Processing should be done.");
$display("Contents of memory and dut after wrap processing:");
dump_mem(6);
dump_dut_state();
// Read and display the A registers.
read_word(ADDR_A0);
$display("A0 after wrap: 0x%08x", read_data);
read_word(ADDR_A1);
$display("A1 after wrap: 0x%08x", read_data);
// Read and display the R blocks that has been processed.
for (i = 0 ; i < 8 ; i = i + 1)
begin
read_word(ADDR_R_DATA0 + i);
$display("mem[0x%07x] = 0x%08x", i, read_data);
end
$display("** TC kwp_ae_128_2 END.\n");
end
endtask // test_kwp_ae_128_2
//----------------------------------------------------------------
// test_kwp_ad_128_1
// Implements unwrap test based on NIST KWP_AE 128 bit key
// with 248 bit plaintext.
//----------------------------------------------------------------
task test_kwp_ad_128_1;
begin : kwp_ad_128_1
integer i;
tc_ctr = tc_ctr + 1;
$display("** TC kwp_ad_128_1 START.");
// Write key and keylength, we also want to decrypt/unwrap.
write_word(ADDR_KEY0, 32'hc03db3cc);
write_word(ADDR_KEY1, 32'h1416dcd1);
write_word(ADDR_KEY2, 32'hc069a195);
write_word(ADDR_KEY3, 32'ha8d77e3d);
write_word(ADDR_CONFIG, 32'h00000000);
// Initialize the AES engine (to expand the key).
// Wait for init to complete.
// Note, not actually needed to wait. We can write R data during init.
$display("* Trying to initialize.");
write_word(ADDR_CTRL, 32'h00000001);
#(2 * CLK_PERIOD);
wait_ready();
$display("* Init should be done.");
// Set the length or R in blocks.
// Write the R bank to be written to.
// Write the R blocks to be processed.
write_word(ADDR_RLEN, 32'h00000004);
write_word(MEM_BASE + 0, 32'h59a69492);
write_word(MEM_BASE + 1, 32'hbb7e2cd0);
write_word(MEM_BASE + 2, 32'h0160d2eb);
write_word(MEM_BASE + 3, 32'hef9bf4d4);
write_word(MEM_BASE + 4, 32'heb16fbf7);
write_word(MEM_BASE + 5, 32'h98f1340f);
write_word(MEM_BASE + 6, 32'h6df6558a);
write_word(MEM_BASE + 7, 32'h4fb84cd0);
// Write magic words to A.
write_word(ADDR_A0, 32'h57e3b669);
write_word(ADDR_A1, 32'h9c6e8177);
$display("* Contents of memory and dut before unwrap processing:");
dump_mem(6);
// Start unwrapping and wait for unwrap to complete.
$display("* Trying to start processing.");
write_word(ADDR_CTRL, 32'h00000002);
#(2 * CLK_PERIOD);
wait_ready();
$display("* Processing should be done.");
$display("Contents of memory and dut after unwrap processing:");
dump_mem(6);
dump_dut_state();
// Read and display the A registers.
read_word(ADDR_A0);
$display("A0 after unwrap: 0x%08x", read_data);
read_word(ADDR_A1);
$display("A1 after unwrap: 0x%08x", read_data);
// Read and display the R blocks that has been processed.
for (i = 0 ; i < 8 ; i = i + 1)
begin
read_word(ADDR_R_DATA0 + i);
$display("mem[0x%07x] = 0x%08x", i, read_data);
end
$display("** TC kwp_ad_128_1 END.\n");
end
endtask // test_kwp_ad_128_1
//----------------------------------------------------------------
// test_kwp_ae_128_2
// Implements wrap test based on NIST KWP_AE 128 bit key with
// 4096 bit plaintext.
//----------------------------------------------------------------
task test_kwp_ae_128_2;
begin : kwp_ae_128_2
integer i;
tc_ctr = tc_ctr + 1;
$display("** TC kwp_ae_128_2 START.");
// Write key and keylength, we also want to encrypt/wrap.
write_word(ADDR_KEY0, 32'h6b8ba9cc);
write_word(ADDR_KEY1, 32'h9b31068b);
write_word(ADDR_KEY2, 32'ha175abfc);
write_word(ADDR_KEY3, 32'hc60c1338);
write_word(ADDR_CONFIG, 32'h00000001);
// Initialize the AES engine (to expand the key).
// Wait for init to complete.
$display("* Trying to initialize.");
write_word(ADDR_CTRL, 32'h00000001);
#(2 * CLK_PERIOD);
wait_ready();
$display("* Init should be done.");
// Set the length or R in blocks.
// Write the R bank to be written to.
// Write the R blocks to be processed.
write_word(ADDR_RLEN, 32'h00000040);
write_word(MEM_BASE + 0, 32'h8af887c5);
write_word(MEM_BASE + 1, 32'h8dfbc38e);
write_word(MEM_BASE + 2, 32'he0423eef);
write_word(MEM_BASE + 3, 32'hcc0e032d);
write_word(MEM_BASE + 4, 32'hcc79dd11);
write_word(MEM_BASE + 5, 32'h6638ca65);
write_word(MEM_BASE + 6, 32'had75dca2);
write_word(MEM_BASE + 7, 32'ha2459f13);
write_word(MEM_BASE + 8, 32'h934dbe61);
write_word(MEM_BASE + 9, 32'ha62cb26d);
write_word(MEM_BASE + 10, 32'h8bbddbab);
write_word(MEM_BASE + 11, 32'hf9bf52bb);
write_word(MEM_BASE + 12, 32'he137ef1d);
write_word(MEM_BASE + 13, 32'h3e30eacf);
write_word(MEM_BASE + 14, 32'h0fe456ec);
write_word(MEM_BASE + 15, 32'h808d6798);
write_word(MEM_BASE + 16, 32'hdc29fe54);
write_word(MEM_BASE + 17, 32'hfa1f784a);
write_word(MEM_BASE + 18, 32'ha3c11cf3);
write_word(MEM_BASE + 19, 32'h94050095);
write_word(MEM_BASE + 20, 32'h81d3f1d5);
write_word(MEM_BASE + 21, 32'h96843813);
write_word(MEM_BASE + 22, 32'ha6685e50);
write_word(MEM_BASE + 23, 32'h3fac8535);
write_word(MEM_BASE + 24, 32'he0c06ecc);
write_word(MEM_BASE + 25, 32'ha8561b6a);
write_word(MEM_BASE + 26, 32'h1f22c578);
write_word(MEM_BASE + 27, 32'heefb6919);
write_word(MEM_BASE + 28, 32'h12be2e16);
write_word(MEM_BASE + 29, 32'h67946101);
write_word(MEM_BASE + 30, 32'hae8c3501);
write_word(MEM_BASE + 31, 32'he6c66eb1);
write_word(MEM_BASE + 32, 32'h7e14f260);
write_word(MEM_BASE + 33, 32'h8c9ce6fb);
write_word(MEM_BASE + 34, 32'hab4a1597);
write_word(MEM_BASE + 35, 32'hed49ccb3);
write_word(MEM_BASE + 36, 32'h930b1060);
write_word(MEM_BASE + 37, 32'hf98c97d8);
write_word(MEM_BASE + 38, 32'hdc4ce81e);
write_word(MEM_BASE + 39, 32'h35279c4d);
write_word(MEM_BASE + 40, 32'h30d1bf86);
write_word(MEM_BASE + 41, 32'hc9b919a3);
write_word(MEM_BASE + 42, 32'hce4f0109);
write_word(MEM_BASE + 43, 32'he77929e5);
write_word(MEM_BASE + 44, 32'h8c4c3aeb);
write_word(MEM_BASE + 45, 32'h5de1ec5e);
write_word(MEM_BASE + 46, 32'h0afa38ae);
write_word(MEM_BASE + 47, 32'h896df912);
write_word(MEM_BASE + 48, 32'h1c72c255);
write_word(MEM_BASE + 49, 32'h141f2f5c);
write_word(MEM_BASE + 50, 32'h9a51be50);
write_word(MEM_BASE + 51, 32'h72547cf8);
write_word(MEM_BASE + 52, 32'ha3b06740);
write_word(MEM_BASE + 53, 32'h4e62f961);
write_word(MEM_BASE + 54, 32'h5a02479c);
write_word(MEM_BASE + 55, 32'hf8c202e7);
write_word(MEM_BASE + 56, 32'hfeb2e258);
write_word(MEM_BASE + 57, 32'h314e0ebe);
write_word(MEM_BASE + 58, 32'h62878a5c);
write_word(MEM_BASE + 59, 32'h4ecd4e9d);
write_word(MEM_BASE + 60, 32'hf7dab2e1);
write_word(MEM_BASE + 61, 32'hfa9a7b53);
write_word(MEM_BASE + 62, 32'h2c2169ac);
write_word(MEM_BASE + 63, 32'hedb7998d);
write_word(MEM_BASE + 64, 32'h5cd8a711);
write_word(MEM_BASE + 65, 32'h8848ce7e);
write_word(MEM_BASE + 66, 32'he9fb2f68);
write_word(MEM_BASE + 67, 32'he28c2b27);
write_word(MEM_BASE + 68, 32'h9ddc064d);
write_word(MEM_BASE + 69, 32'hb70ad73c);
write_word(MEM_BASE + 70, 32'h6dbe10c5);
write_word(MEM_BASE + 71, 32'he1c56a70);
write_word(MEM_BASE + 72, 32'h9c1407f9);
write_word(MEM_BASE + 73, 32'h3a727cce);
write_word(MEM_BASE + 74, 32'h1075103a);
write_word(MEM_BASE + 75, 32'h4009ae2f);
write_word(MEM_BASE + 76, 32'h7731b7d7);
write_word(MEM_BASE + 77, 32'h1756eee1);
write_word(MEM_BASE + 78, 32'h19b828ef);
write_word(MEM_BASE + 79, 32'h4ed61eff);
write_word(MEM_BASE + 80, 32'h16493553);
write_word(MEM_BASE + 81, 32'h2a94fa8f);
write_word(MEM_BASE + 82, 32'he62dc2e2);
write_word(MEM_BASE + 83, 32'h2cf20f16);
write_word(MEM_BASE + 84, 32'h8ae65f4b);
write_word(MEM_BASE + 85, 32'h6785286c);
write_word(MEM_BASE + 86, 32'h253f365f);
write_word(MEM_BASE + 87, 32'h29453a47);
write_word(MEM_BASE + 88, 32'h9dc2824b);
write_word(MEM_BASE + 89, 32'h8bdabd96);
write_word(MEM_BASE + 90, 32'h2da3b76a);
write_word(MEM_BASE + 91, 32'he9c8a720);
write_word(MEM_BASE + 92, 32'h155e158f);
write_word(MEM_BASE + 93, 32'he389c8cc);
write_word(MEM_BASE + 94, 32'h7fa6ad52);
write_word(MEM_BASE + 95, 32'h2c951b5c);
write_word(MEM_BASE + 96, 32'h236bf964);
write_word(MEM_BASE + 97, 32'hb5b1bfb0);
write_word(MEM_BASE + 98, 32'h98a39835);
write_word(MEM_BASE + 99, 32'h759b9540);
write_word(MEM_BASE + 100, 32'h4b72b17f);
write_word(MEM_BASE + 101, 32'h7dbcda93);
write_word(MEM_BASE + 102, 32'h6177ae05);
write_word(MEM_BASE + 103, 32'h9269f41e);
write_word(MEM_BASE + 104, 32'hcdac81a4);
write_word(MEM_BASE + 105, 32'h9f5bbfd2);
write_word(MEM_BASE + 106, 32'he801392a);
write_word(MEM_BASE + 107, 32'h043ef068);
write_word(MEM_BASE + 108, 32'h73550a67);
write_word(MEM_BASE + 109, 32'hfcbc039f);
write_word(MEM_BASE + 110, 32'h0b5d30ce);
write_word(MEM_BASE + 111, 32'h490baa97);
write_word(MEM_BASE + 112, 32'h9dbbaf9e);
write_word(MEM_BASE + 113, 32'h53d45d7e);
write_word(MEM_BASE + 114, 32'h2dff26b2);
write_word(MEM_BASE + 115, 32'hf7e6628d);
write_word(MEM_BASE + 116, 32'hed694217);
write_word(MEM_BASE + 117, 32'ha39f454b);
write_word(MEM_BASE + 118, 32'h288e7906);
write_word(MEM_BASE + 119, 32'hb79faf4a);
write_word(MEM_BASE + 120, 32'h407a7d20);
write_word(MEM_BASE + 121, 32'h7646f930);
write_word(MEM_BASE + 122, 32'h96a157f0);
write_word(MEM_BASE + 123, 32'hd1dca05a);
write_word(MEM_BASE + 124, 32'h7f92e318);
write_word(MEM_BASE + 125, 32'hfc1ff62c);
write_word(MEM_BASE + 126, 32'he2de7f12);
write_word(MEM_BASE + 127, 32'h9b187053);
// Write magic words to A.
write_word(ADDR_A0, 32'ha65959a6);
write_word(ADDR_A1, 32'h00000200);
$display("* Contents of memory and dut before wrap processing:");
dump_mem(65);
// Start wrapping and wait for wrap to complete.
$display("* Trying to start processing.");
write_word(ADDR_CTRL, 32'h00000002);
#(2 * CLK_PERIOD);
wait_ready();
$display("* Processing should be done.");
$display("Contents of memory and dut after wrap processing:");
dump_mem(65);
dump_dut_state();
// Read and display the A registers.
read_word(ADDR_A0);
$display("A0 after wrap: 0x%08x", read_data);
read_word(ADDR_A1);
$display("A1 after wrap: 0x%08x", read_data);
// Read and display the R blocks that has been processed.
for (i = 0 ; i < 128 ; i = i + 1)
begin
read_word(ADDR_R_DATA0 + i);
$display("mem[0x%07x] = 0x%08x", i, read_data);
end
$display("** TC kwp_ae_128_2 END.\n");
end
endtask // test_kwp_ae_128_2
//----------------------------------------------------------------
// test_kwp_ad_128_2
// Implements unwrap test based on NIST KWP_AD 128 bit key with
// 4096 bit plaintext.
//----------------------------------------------------------------
task test_kwp_ad_128_2;
begin : kwp_ad_128_2
integer i;
tc_ctr = tc_ctr + 1;
$display("** TC kwp_ad_128_2 START.");
// Write key and keylength, we also want to unwrap/decrypt.
write_word(ADDR_KEY0, 32'h6b8ba9cc);
write_word(ADDR_KEY1, 32'h9b31068b);
write_word(ADDR_KEY2, 32'ha175abfc);
write_word(ADDR_KEY3, 32'hc60c1338);
write_word(ADDR_CONFIG, 32'h00000000);
// Initialize the AES engine (to expand the key).
// Wait for init to complete.
$display("* Trying to initialize.");
write_word(ADDR_CTRL, 32'h00000001);
#(2 * CLK_PERIOD);
wait_ready();
$display("* Init should be done.");
// Set the length or R in blocks.
// Write the R bank to be written to.
// Write the R blocks to be processed.
write_word(ADDR_RLEN, 32'h00000040);
write_word(MEM_BASE + 0, 32'h4501c1ec);
write_word(MEM_BASE + 1, 32'hadc6b5e3);
write_word(MEM_BASE + 2, 32'hf1c23c29);
write_word(MEM_BASE + 3, 32'heca60890);
write_word(MEM_BASE + 4, 32'h5f9cabdd);
write_word(MEM_BASE + 5, 32'h46e34a55);
write_word(MEM_BASE + 6, 32'he1f7ac83);
write_word(MEM_BASE + 7, 32'h08e75c90);
write_word(MEM_BASE + 8, 32'h3675982b);
write_word(MEM_BASE + 9, 32'hda99173a);
write_word(MEM_BASE + 10, 32'h2ba57d2c);
write_word(MEM_BASE + 11, 32'hcf2e01a0);
write_word(MEM_BASE + 12, 32'h2589f89d);
write_word(MEM_BASE + 13, 32'hfd4b3c7f);
write_word(MEM_BASE + 14, 32'hd229ec91);
write_word(MEM_BASE + 15, 32'hc9d0c46e);
write_word(MEM_BASE + 16, 32'ha5dee3c0);
write_word(MEM_BASE + 17, 32'h48cd4611);
write_word(MEM_BASE + 18, 32'hbfeadc9b);
write_word(MEM_BASE + 19, 32'hf26daa1e);
write_word(MEM_BASE + 20, 32'h02cb72e2);
write_word(MEM_BASE + 21, 32'h22cf3dab);
write_word(MEM_BASE + 22, 32'h120dd1e8);
write_word(MEM_BASE + 23, 32'hc2dd9bd5);
write_word(MEM_BASE + 24, 32'h8bbefa5d);
write_word(MEM_BASE + 25, 32'h14526abd);
write_word(MEM_BASE + 26, 32'h1e8d2170);
write_word(MEM_BASE + 27, 32'ha6ba8283);
write_word(MEM_BASE + 28, 32'hc243ec2f);
write_word(MEM_BASE + 29, 32'hd5ef0703);
write_word(MEM_BASE + 30, 32'h0b1ef5f6);
write_word(MEM_BASE + 31, 32'h9f9620e4);
write_word(MEM_BASE + 32, 32'hb17a3639);
write_word(MEM_BASE + 33, 32'h34100588);
write_word(MEM_BASE + 34, 32'h7b9ffc79);
write_word(MEM_BASE + 35, 32'h35335947);
write_word(MEM_BASE + 36, 32'h03e5dcae);
write_word(MEM_BASE + 37, 32'h67bd0ce7);
write_word(MEM_BASE + 38, 32'ha3c98ca6);
write_word(MEM_BASE + 39, 32'h5815a4d0);
write_word(MEM_BASE + 40, 32'h67f27e6e);
write_word(MEM_BASE + 41, 32'h66d6636c);
write_word(MEM_BASE + 42, 32'hebb78973);
write_word(MEM_BASE + 43, 32'h2566a52a);
write_word(MEM_BASE + 44, 32'hc3970e14);
write_word(MEM_BASE + 45, 32'hc37310dc);
write_word(MEM_BASE + 46, 32'h2fcee0e7);
write_word(MEM_BASE + 47, 32'h39a16291);
write_word(MEM_BASE + 48, 32'h029fd2b4);
write_word(MEM_BASE + 49, 32'hd534e304);
write_word(MEM_BASE + 50, 32'h45474b26);
write_word(MEM_BASE + 51, 32'h711a8b3e);
write_word(MEM_BASE + 52, 32'h1ee3cc88);
write_word(MEM_BASE + 53, 32'hb09e8b17);
write_word(MEM_BASE + 54, 32'h45b6cc0f);
write_word(MEM_BASE + 55, 32'h067624ec);
write_word(MEM_BASE + 56, 32'hb232db75);
write_word(MEM_BASE + 57, 32'h0b01fe54);
write_word(MEM_BASE + 58, 32'h57fdea77);
write_word(MEM_BASE + 59, 32'hb251b10f);
write_word(MEM_BASE + 60, 32'he95d3eee);
write_word(MEM_BASE + 61, 32'hdb083bdf);
write_word(MEM_BASE + 62, 32'h109c41db);
write_word(MEM_BASE + 63, 32'ha26cc965);
write_word(MEM_BASE + 64, 32'h4f787bf9);
write_word(MEM_BASE + 65, 32'h5735ff07);
write_word(MEM_BASE + 66, 32'h070b175c);
write_word(MEM_BASE + 67, 32'hea8b6230);
write_word(MEM_BASE + 68, 32'h2e6087b9);
write_word(MEM_BASE + 69, 32'h1a041547);
write_word(MEM_BASE + 70, 32'h46056910);
write_word(MEM_BASE + 71, 32'h99f1a9e2);
write_word(MEM_BASE + 72, 32'hb626c4b3);
write_word(MEM_BASE + 73, 32'hbb7aeb8e);
write_word(MEM_BASE + 74, 32'had9922bc);
write_word(MEM_BASE + 75, 32'h3617cb42);
write_word(MEM_BASE + 76, 32'h7c669b88);
write_word(MEM_BASE + 77, 32'hbe5f98ae);
write_word(MEM_BASE + 78, 32'ha7edb8b0);
write_word(MEM_BASE + 79, 32'h063bec80);
write_word(MEM_BASE + 80, 32'haf4c081f);
write_word(MEM_BASE + 81, 32'h89778d7c);
write_word(MEM_BASE + 82, 32'h7242ddae);
write_word(MEM_BASE + 83, 32'h88e8d3af);
write_word(MEM_BASE + 84, 32'hf1f80e57);
write_word(MEM_BASE + 85, 32'h5e1aab4a);
write_word(MEM_BASE + 86, 32'h5d115bc2);
write_word(MEM_BASE + 87, 32'h7636fd14);
write_word(MEM_BASE + 88, 32'hd19bc594);
write_word(MEM_BASE + 89, 32'h33f69763);
write_word(MEM_BASE + 90, 32'h5ecd870d);
write_word(MEM_BASE + 91, 32'h17e7f5b0);
write_word(MEM_BASE + 92, 32'h04dee400);
write_word(MEM_BASE + 93, 32'h1cddc34a);
write_word(MEM_BASE + 94, 32'hb6e377ee);
write_word(MEM_BASE + 95, 32'hb3fb08e9);
write_word(MEM_BASE + 96, 32'h47697076);
write_word(MEM_BASE + 97, 32'h5105d93e);
write_word(MEM_BASE + 98, 32'h4558fe3d);
write_word(MEM_BASE + 99, 32'h4fc6fe05);
write_word(MEM_BASE + 100, 32'h3aab9c6c);
write_word(MEM_BASE + 101, 32'hf032f111);
write_word(MEM_BASE + 102, 32'h6e70c2d6);
write_word(MEM_BASE + 103, 32'h5f7c8cde);
write_word(MEM_BASE + 104, 32'hb6ad63ac);
write_word(MEM_BASE + 105, 32'h4291f93d);
write_word(MEM_BASE + 106, 32'h467ebbb2);
write_word(MEM_BASE + 107, 32'h9ead265c);
write_word(MEM_BASE + 108, 32'h05ac684d);
write_word(MEM_BASE + 109, 32'h20a6bef0);
write_word(MEM_BASE + 110, 32'h9b71830f);
write_word(MEM_BASE + 111, 32'h717e08bc);
write_word(MEM_BASE + 112, 32'hb4f9d377);
write_word(MEM_BASE + 113, 32'h3bec928f);
write_word(MEM_BASE + 114, 32'h66eeb64d);
write_word(MEM_BASE + 115, 32'hc451e958);
write_word(MEM_BASE + 116, 32'he357ebbf);
write_word(MEM_BASE + 117, 32'hef5a342d);
write_word(MEM_BASE + 118, 32'hf28707ac);
write_word(MEM_BASE + 119, 32'h4b8e3e8c);
write_word(MEM_BASE + 120, 32'h854e8d69);
write_word(MEM_BASE + 121, 32'h1cb92e87);
write_word(MEM_BASE + 122, 32'hc0d57558);
write_word(MEM_BASE + 123, 32'he44cd754);
write_word(MEM_BASE + 124, 32'h424865c2);
write_word(MEM_BASE + 125, 32'h29c9e1ab);
write_word(MEM_BASE + 126, 32'hb28e003b);
write_word(MEM_BASE + 127, 32'h6819400b);
// Write magic words to A.
write_word(ADDR_A0, 32'haea19443);
write_word(ADDR_A1, 32'hd7f8ad7d);
$display("* Contents of memory and dut before unwrap processing:");
dump_mem(65);
// Start unwrapping and wait for unwrap to complete.
$display("* Trying to start processing.");
write_word(ADDR_CTRL, 32'h00000002);
#(2 * CLK_PERIOD);
wait_ready();
$display("* Processing should be done.");
$display("Contents of memory and dut after unwrap processing:");
dump_mem(65);
dump_dut_state();
// Read and display the A registers.
read_word(ADDR_A0);
$display("A0 after unwrap: 0x%08x", read_data);
read_word(ADDR_A1);
$display("A1 after unwrap: 0x%08x", read_data);
// Read and display the R blocks that has been processed.
for (i = 0 ; i < 128 ; i = i + 1)
begin
read_word(ADDR_R_DATA0 + i);
$display("mem[0x%07x] = 0x%08x", i, read_data);
end
$display("** TC kwp_ad_128_2 END.\n");
end
endtask // test_kwp_ad_128_2
//----------------------------------------------------------------
// main
//----------------------------------------------------------------
initial
begin : main
$display(" -= Testbench for Keywrap started =-");
$display(" ==================================");
$display("");
init_sim();
dump_dut_state();
reset_dut();
dump_dut_state();
test_core_access();
test_kwp_ae_128_1();
test_kwp_ad_128_1();
test_kwp_ae_128_2();
test_kwp_ad_128_2();
display_test_results();
$display("");
$display(" -= Testbench for Keywrap completed =-");
$display(" ====================================");
$finish;
end // main
endmodule // tb_keywrap
//======================================================================
// EOF tb_keywrap.v
//======================================================================