//======================================================================
//
// Copyright (c) 2016, NORDUnet A/S All rights reserved.
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//
//======================================================================
`timescale 1ns / 1ps
module modexpa7_buffer_core
#(parameter OPERAND_ADDR_WIDTH = 5) // 1024 / 32 = 32 -> 5 bits
(
input wire clk,
input wire [OPERAND_ADDR_WIDTH:0] rw_coeff_bram_addr,
input wire rw_coeff_bram_wr,
input wire [31:0] rw_coeff_bram_in,
output wire [31:0] rw_coeff_bram_out,
input wire [OPERAND_ADDR_WIDTH:0] rw_mm_bram_addr,
input wire rw_mm_bram_wr,
input wire [31:0] rw_mm_bram_in,
output wire [31:0] rw_mm_bram_out,
input wire [OPERAND_ADDR_WIDTH:0] rw_nn_bram_addr,
input wire rw_nn_bram_wr,
input wire [31:0] rw_nn_bram_in,
input wire [OPERAND_ADDR_WIDTH:0] rw_y_bram_addr,
input wire rw_y_bram_wr,
input wire [31:0] rw_y_bram_in,
output wire [31:0] rw_y_bram_out,
input wire [OPERAND_ADDR_WIDTH:0] rw_r_bram_addr,
input wire rw_r_bram_wr,
input wire [31:0] rw_r_bram_in,
output wire [31:0] rw_r_bram_out,
input wire [OPERAND_ADDR_WIDTH:0] rw_t_bram_addr,
input wire rw_t_bram_wr,
input wire [31:0] rw_t_bram_in,
output wire [31:0] rw_t_bram_out,
input wire [OPERAND_ADDR_WIDTH:0] ro_coeff_bram_addr,
output wire [31:0] ro_coeff_bram_out,
input wire [OPERAND_ADDR_WIDTH:0] ro_mm_bram_addr,
output wire [31:0] ro_mm_bram_out,
input wire [OPERAND_ADDR_WIDTH:0] ro_nn_bram_addr,
output wire [31:0] ro_nn_bram_out,
input wire [OPERAND_ADDR_WIDTH:0] ro_r_bram_addr,
output wire [31:0] ro_r_bram_out,
input wire [OPERAND_ADDR_WIDTH:0] ro_t_bram_addr,
output wire [31:0] ro_t_bram_out
);
//
// Montgomery Coefficient
//
ram_1rw_1ro_readfirst #
(
.MEM_WIDTH (32),
.MEM_ADDR_BITS (OPERAND_ADDR_WIDTH+1)
)
mem_coeff
(
.clk (clk),
.a_addr (rw_coeff_bram_addr),
.a_wr (rw_coeff_bram_wr),
.a_in (rw_coeff_bram_in),
.a_out (rw_coeff_bram_out),
.b_addr (ro_coeff_bram_addr),
.b_out (ro_coeff_bram_out)
);
//
// Powers of Message
//
ram_1rw_1ro_readfirst #
(
.MEM_WIDTH (32),
.MEM_ADDR_BITS (OPERAND_ADDR_WIDTH+1)
)
mem_mm
(
.clk (clk),
.a_addr (rw_mm_bram_addr),
.a_wr (rw_mm_bram_wr),
.a_in (rw_mm_bram_in),
.a_out (rw_mm_bram_out),
.b_addr (ro_mm_bram_addr),
.b_out (ro_mm_bram_out)
);
//
// Extended Modulus
//
ram_1rw_1ro_readfirst #
(
.MEM_WIDTH (32),
.MEM_ADDR_BITS (OPERAND_ADDR_WIDTH+1)
)
mem_nn
(
.clk (clk),
.a_addr (rw_nn_bram_addr),
.a_wr (rw_nn_bram_wr),
.a_in (rw_nn_bram_in),
.a_out (),
.b_addr (ro_nn_bram_addr),
.b_out (ro_nn_bram_out)
);
//
// Output
//
ram_1rw_1ro_readfirst #
(
.MEM_WIDTH (32),
.MEM_ADDR_BITS (OPERAND_ADDR_WIDTH+1)
)
mem_y
(
.clk (clk),
.a_addr (rw_y_bram_addr),
.a_wr (rw_y_bram_wr),
.a_in (rw_y_bram_in),
.a_out (rw_y_bram_out),
.b_addr ({(OPERAND_ADDR_WIDTH+1){1'b0}}),
.b_out ()
);
//
// Result of Multiplication
//
ram_1rw_1ro_readfirst #
(
.MEM_WIDTH (32),
.MEM_ADDR_BITS (OPERAND_ADDR_WIDTH+1)
)
mem_r
(
.clk (clk),
.a_addr (rw_r_bram_addr),
.a_wr (rw_r_bram_wr),
.a_in (rw_r_bram_in),
.a_out (rw_r_bram_out),
.b_addr (ro_r_bram_addr),
.b_out (ro_r_bram_out)
);
//
// Temporary Buffer
//
ram_1rw_1ro_readfirst #
(
.MEM_WIDTH (32),
.MEM_ADDR_BITS (OPERAND_ADDR_WIDTH+1)
)
mem_t
(
.clk (clk),
.a_addr (rw_t_bram_addr),
.a_wr (rw_t_bram_wr),
.a_in (rw_t_bram_in),
.a_out (rw_t_bram_out),
.b_addr (ro_t_bram_addr),
.b_out (ro_t_bram_out)
);
endmodule