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schengopen |
////////////////////////////////////////////////////////////////// ////
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//// ////
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//// AES Decryption Core for FPGA ////
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//// ////
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//// This file is part of the AES Decryption Core for FPGA project ////
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//// http://www.opencores.org/cores/xxx/ ////
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//// ////
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//// Description ////
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//// Implementation of AES Decryption Core for FPGA according to ////
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//// core specification document. ////
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//// ////
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//// To Do: ////
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//// - ////
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//// ////
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//// Author(s): ////
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//// - scheng, schengopencores@opencores.org ////
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//// ////
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//////////////////////////////////////////////////////////////////////
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//// ////
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//// Copyright (C) 2009 Authors and OPENCORES.ORG ////
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//// ////
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//// This source file may be used and distributed without ////
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//// restriction provided that this copyright statement is not ////
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//// removed from the file and that any derivative work contains ////
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//// the original copyright notice and the associated disclaimer. ////
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//// ////
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//// This source file is free software; you can redistribute it ////
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//// and/or modify it under the terms of the GNU Lesser General ////
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//// Public License as published by the Free Software Foundation; ////
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//// either version 2.1 of the License, or (at your option) any ////
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//// later version. ////
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//// ////
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//// This source is distributed in the hope that it will be ////
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//// useful, but WITHOUT ANY WARRANTY; without even the implied ////
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//// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ////
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//// PURPOSE. See the GNU Lesser General Public License for more ////
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//// details. ////
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//// ////
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//// You should have received a copy of the GNU Lesser General ////
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//// Public License along with this source; if not, download it ////
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//// from http://www.opencores.org/lgpl.shtml ////
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//// //// ///
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///////////////////////////////////////////////////////////////////
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//// ////
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//// 128-bit key expander ////
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//// ////
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//// The key expansion algorithm is described in section 5.2 of the ////
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//// FIPS-197 spec. This file implements the case for 128-bit key ////
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//// only. ////
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//// ////
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////////////////////////////////////////////////////////////////////////
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module KeyExpand128(
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// 128-bit key expander
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input [0:127] kt,
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input kt_vld, // Active high input informing key expander that a valid new key is present at kt.
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output kt_rdy, // Active high output indicates key expander ready to accept new key
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output [0:127] rkey,
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output rkey_vld, // Active high output indicates valid roundkey available at rkey[0:127]
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output rkey_last, // High for 1 clock cycle, indicates last roundkey available at rkey[0:127].
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input clk,
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input rst
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);
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// Registers holding the current roundkey
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logic [0:31] w0;
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logic [0:31] w1;
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logic [0:31] w2;
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logic [0:31] w3;
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logic [0:3] keyexp_state; // Key expansion state machine.
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logic [0:7] Rcon; // Round constant. See FIPS-197 section 5.3.
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wire [0:31] subword_out;
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wire [0:31] rotword_out;
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wire [0:31] w0_feed;
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wire [0:31] w1_feed;
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wire [0:31] w2_feed;
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wire [0:31] w3_feed;
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wire keyexp_state_0; // '1' indicates key expansion state machine at state 0 (initial state)
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wire keyexp_state_10; // '1' indicates key expansion state machine at state 10 (last state)
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// Do not remove the "keep" and "max_fanout" attribute. They are there to force the synthesizer
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// to infer independent logic for next_w0-3, instead of deriving next_w1 from next_w0, ...and
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// so on. See the definitions of next_w* below. This is to avoid getting a chain of LUTs, which reduces Fmax.
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(* keep = "true", max_fanout = 1 *) wire [0:31] next_w0;
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(* keep = "true", max_fanout = 1 *) wire [0:31] next_w1;
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(* keep = "true", max_fanout = 1 *) wire [0:31] next_w2;
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(* keep = "true", max_fanout = 1 *) wire [0:31] next_w3;
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assign w0_feed = (keyexp_state_0)? kt[0+:32] : w0;
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assign w1_feed = (keyexp_state_0)? kt[32+:32] : w1;
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assign w2_feed = (keyexp_state_0)? kt[64+:32] : w2;
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assign w3_feed = (keyexp_state_0)? kt[96+:32] : w3;
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RotWord RotWord_u(.din(w3_feed), .dout(rotword_out));
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SubWord SubWord_u(.din(rotword_out), .dout(subword_out));
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assign next_w0 = subword_out ^ {Rcon,24'h000000} ^ w0_feed;
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assign next_w1 = subword_out ^ {Rcon,24'h000000} ^ w0_feed ^ w1_feed;
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assign next_w2 = subword_out ^ {Rcon,24'h000000} ^ w0_feed ^ w1_feed ^ w2_feed;
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assign next_w3 = subword_out ^ {Rcon,24'h000000} ^ w0_feed ^ w1_feed ^ w2_feed ^ w3_feed;
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assign rkey = (keyexp_state_0)? kt : {w0,w1,w2,w3};
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assign kt_rdy = keyexp_state_0; // Only accept new key in initial state.
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assign rkey_vld = ~keyexp_state_0 | kt_vld;
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assign rkey_last = keyexp_state_10;
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assign keyexp_state_0 = (keyexp_state == 0);
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assign keyexp_state_10 = (keyexp_state == 10);
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// Key Expansion state machine
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always_ff @(posedge clk)
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begin
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if (rst)
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begin
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keyexp_state <= 0; // Reset to initial state
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Rcon <= 8'h01;
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end
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else
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unique case (keyexp_state)
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if (kt_vld)
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begin
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keyexp_state <= keyexp_state + 1;
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{w0,w1,w2,w3} <= {next_w0, next_w1, next_w2, next_w3};
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Rcon <= (Rcon[0])? (Rcon << 1) ^ 8'h1b : (Rcon << 1); // Advance to next Rcon value.
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end
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1,2,3,4,5,6,7,8,9 :
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// Proceed to next state and update roundkey register
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begin
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keyexp_state <= keyexp_state + 1;
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{w0,w1,w2,w3} <= {next_w0, next_w1, next_w2, next_w3};
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Rcon <= (Rcon[0])? (Rcon << 1) ^ 8'h1b : (Rcon << 1); // Advance to next Rcon value.
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end
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10: // Wrap back to initial state and update roundkey register
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begin
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keyexp_state <= 0;
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{w0,w1,w2,w3} <= {next_w0, next_w1, next_w2, next_w3};
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Rcon <= 8'h01;
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end
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endcase
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end
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endmodule
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