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ecc_montgomerymultiplier_tb.sv
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ecc_montgomerymultiplier_tb.sv
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// SPDX-License-Identifier: Apache-2.0
//
// Licensed under the Apache 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://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the 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.
//
//======================================================================
//
// mm_tb.sv
// --------
//
//
//
//======================================================================
module ecc_montgomerymultiplier_tb #(
parameter OPERAND_WIDTH = 16,
parameter WORD_WIDTH = 4,
parameter TEST_VECTOR_NUM = 5
)
();
//----------------------------------------------------------------
// Internal constant and parameter definitions.
//----------------------------------------------------------------
parameter CLK_HALF_PERIOD = 1;
parameter CLK_PERIOD = 2 * CLK_HALF_PERIOD;
localparam TEST_VECTOR_ID_WIDTH = $clog2(TEST_VECTOR_NUM);
localparam STAT_CNT_WIDTH = 64;
localparam int unsigned S_NUM = $ceil(real'(OPERAND_WIDTH) / WORD_WIDTH) + 1;
// NOTE: This is for Optimized FIOS Montgomery Multiplication Algorithm.
// It can be changed for other algorithms.
localparam R_WIDTH = S_NUM * WORD_WIDTH + 1;
//----------------------------------------------------------------
// Type definitions
//----------------------------------------------------------------
typedef bit [STAT_CNT_WIDTH-1:0] stat_t;
typedef bit [OPERAND_WIDTH-1:0] operand_t;
typedef bit [WORD_WIDTH-1:0] word_t;
typedef bit [TEST_VECTOR_ID_WIDTH-1:0] test_vector_id_t;
typedef bit [R_WIDTH-1:0] r_t;
typedef struct packed {
operand_t a;
operand_t b;
//operand_t r_inverse; // inverse is modulo 'n', therefore it has operand_t type
operand_t n;
r_t n_prime; // n' = -n^(-1) mod r, therefore it is wider and has r_t type
operand_t product;
} test_vector_t;
//----------------------------------------------------------------
// Register and Wire declarations.
//----------------------------------------------------------------
stat_t cycle_ctr;
stat_t error_ctr;
stat_t tc_ctr;
logic clk_tb;
logic reset_n_tb;
logic start_i_tb;
operand_t opa_i_tb;
operand_t opb_i_tb;
operand_t n_i_tb;
word_t n_prime_i_tb;
operand_t p_o_tb;
logic ready_tb;
int test_vector_cnt;
test_vector_t [TEST_VECTOR_NUM-1:0] test_vectors;
//----------------------------------------------------------------
// Device Under Test.
//----------------------------------------------------------------
ecc_montgomerymultiplier #(
.REG_SIZE (OPERAND_WIDTH),
.RADIX (WORD_WIDTH)
)
mm_dut (
.clk (clk_tb),
.reset_n (reset_n_tb),
.zeroize (1'b0),
.start_i (start_i_tb),
.opa_i (opa_i_tb),
.opb_i (opb_i_tb),
.n_i (n_i_tb),
.n_prime_i (n_prime_i_tb),
.p_o (p_o_tb),
.ready_o (ready_tb)
);
//----------------------------------------------------------------
// clk_gen
//
// Always running clock generator process.
//----------------------------------------------------------------
always
begin : clk_gen
#CLK_HALF_PERIOD;
clk_tb = !clk_tb;
end
//----------------------------------------------------------------
// sys_monitor()
//
// An always running process that creates a cycle counter and
// conditionally displays information about the DUT.
//----------------------------------------------------------------
always
begin : sys_monitor
#(CLK_PERIOD);
cycle_ctr = cycle_ctr + 1;
end
//----------------------------------------------------------------
// reset_dut()
//
// Toggle reset to put the DUT into a well known state.
//----------------------------------------------------------------
task reset_dut;
begin
$display("*** Toggle reset.");
reset_n_tb = 0;
#(2 * CLK_PERIOD);
reset_n_tb = 1;
$display("");
end
endtask // reset_dut
//----------------------------------------------------------------
// 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);
$display("* TESTCASE PASSED");
end
else
begin
$display("*** %02d tests completed - %02d test cases did not complete successfully.",
tc_ctr, error_ctr);
$display("* TESTCASE FAILED");
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;
clk_tb = 0;
reset_n_tb = 0;
start_i_tb = 0;
opa_i_tb = '0;
opb_i_tb = '0;
n_i_tb = '0;
n_prime_i_tb = '0;
end
endtask // init_sim
//----------------------------------------------------------------
// wait_ready()
//
// Initialize all counters and testbed functionality as well
// as setting the DUT inputs to defined values.
//----------------------------------------------------------------
task wait_ready;
begin
while (ready_tb == 0)
begin
#CLK_PERIOD;
end
end
endtask // init_sim
//----------------------------------------------------------------
// mm_single_block_test()
//
// Perform a single Montgomery multiplication block test.
//----------------------------------------------------------------
task mm_single_block_test(input [7 : 0] tc_number,
input test_vector_t test_vector);
begin
$display("*** TC %0d mm test started.", tc_number);
tc_ctr = tc_ctr + 1;
$display("Computing product of:\n0x%0x\n0x%0x\nmod 0x%0x\n", test_vector.a, test_vector.b, test_vector.n);
opa_i_tb = test_vector.a;
opb_i_tb = test_vector.b;
n_i_tb = test_vector.n;
//only need to pass the last few bits of n_prime
n_prime_i_tb = test_vector.n_prime[WORD_WIDTH-1:0];
#CLK_PERIOD;
start_i_tb = 1;
#CLK_PERIOD;
start_i_tb = 0;
wait_ready();
if (p_o_tb == test_vector.product)
begin
$display("*** TC %0d successful.", tc_number);
$display("");
end
else
begin
$display("*** ERROR: TC %0d NOT successful.", tc_number);
$display("Expected: 0x%032x", test_vector.product);
$display("Got: 0x%032x", p_o_tb);
$display("");
error_ctr = error_ctr + 1;
end
end
endtask // mm_single_block_test
//----------------------------------------------------------------
// mm_test()
//
//----------------------------------------------------------------
task mm_test;
for (int i = 0; i < test_vector_cnt; i++) begin: test_vector_loop
mm_single_block_test(i, test_vectors[i]);
end
endtask
task read_test_vectors(input string fname);
integer values_per_test_vector;
integer line_cnt;
integer fin;
integer rv;
r_t val; // must be the largest width of any possible value
test_vector_t test_vector;
// ATTN: Must match the number of fields generated by gen_mm_test_vectors.py script
values_per_test_vector = 6;
line_cnt = 0;
test_vector_cnt = 0;
fin = $fopen(fname, "r");
if (fin == 0)
$error("Can't open file %s", fname);
while (!$feof(fin)) begin
rv = $fscanf(fin, "%h\n", val);
if (rv != 1) begin
$error("Failed to read a matching string");
$fclose(fin);
$finish;
end
// ATTN: the number of cases must be equal to 'values_per_test_vector'.
// ATTN: the order of values must be the same as in gen_mm_test_vectors.py script.
case (line_cnt % values_per_test_vector)
0: test_vector.a = val;
1: test_vector.b = val;
//2: test_vector.r_inverse = val;
2: test_vector.n = val;
3: test_vector.n_prime = val;
4: begin
test_vector.product = val;
test_vectors[test_vector_cnt] = test_vector;
end
5 : test_vector_cnt++;
endcase
line_cnt++;
end
$fclose(fin);
$display("Read %0d test vectors from %s", test_vector_cnt, fname);
endtask
//----------------------------------------------------------------
// main
//
// The main test functionality.
//----------------------------------------------------------------
initial
begin : main
string fname;
$display(" -= Testbench for mm started =-");
$display(" ==============================\n");
fname = $sformatf("mm_test_vectors_%0d_key_%0d_word_%0d.hex", TEST_VECTOR_NUM, OPERAND_WIDTH, WORD_WIDTH);
read_test_vectors(fname);
init_sim();
reset_dut();
mm_test();
display_test_results();
$display("");
$display("*** mm simulation done. ***");
$finish;
end // main
endmodule // mm_tb