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|
//======================================================================
//
// sha512.v
// --------
// Top level wrapper for the SHA-512 hash function providing
// a simple memory like interface with 32 bit data access.
//
//
// Author: Joachim Strombergson
// Copyright (c) 2014, 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 sha512(
// Clock and reset.
input wire clk,
input wire reset_n,
// Control.
input wire cs,
input wire we,
// Data ports.
input wire [7 : 0] address,
input wire [31 : 0] write_data,
output wire [31 : 0] read_data,
output wire error
);
//----------------------------------------------------------------
// Internal constant and parameter definitions.
//----------------------------------------------------------------
parameter ADDR_NAME0 = 8'h00;
parameter ADDR_NAME1 = 8'h01;
parameter ADDR_VERSION = 8'h02;
parameter ADDR_CTRL = 8'h08;
parameter CTRL_INIT_BIT = 0;
parameter CTRL_NEXT_BIT = 1;
parameter CTRL_MODE_LOW_BIT = 2;
parameter CTRL_MODE_HIGH_BIT = 3;
parameter CTRL_WORK_FACTOR_BIT = 7;
parameter ADDR_STATUS = 8'h09;
parameter STATUS_READY_BIT = 0;
parameter STATUS_VALID_BIT = 1;
parameter ADDR_WORK_FACTOR_NUM = 8'h0a;
parameter ADDR_BLOCK0 = 8'h10;
parameter ADDR_BLOCK31 = 8'h2f;
parameter ADDR_DIGEST0 = 8'h40;
parameter ADDR_DIGEST1 = 8'h41;
parameter ADDR_DIGEST2 = 8'h42;
parameter ADDR_DIGEST3 = 8'h43;
parameter ADDR_DIGEST4 = 8'h44;
parameter ADDR_DIGEST5 = 8'h45;
parameter ADDR_DIGEST6 = 8'h46;
parameter ADDR_DIGEST7 = 8'h47;
parameter ADDR_DIGEST8 = 8'h48;
parameter ADDR_DIGEST9 = 8'h49;
parameter ADDR_DIGEST10 = 8'h4a;
parameter ADDR_DIGEST11 = 8'h4b;
parameter ADDR_DIGEST12 = 8'h4c;
parameter ADDR_DIGEST13 = 8'h4d;
parameter ADDR_DIGEST14 = 8'h4e;
parameter ADDR_DIGEST15 = 8'h4f;
parameter CORE_NAME0 = 32'h73686132; // "sha2"
parameter CORE_NAME1 = 32'h2d353132; // "-512"
parameter CORE_VERSION = 32'h302e3831; // "0.81"
parameter MODE_SHA_512_224 = 2'h0;
parameter MODE_SHA_512_256 = 2'h1;
parameter MODE_SHA_384 = 2'h2;
parameter MODE_SHA_512 = 2'h3;
parameter DEFAULT_WORK_FACTOR_NUM = 32'h000f0000;
//----------------------------------------------------------------
// Registers including update variables and write enable.
//----------------------------------------------------------------
reg init_reg;
reg init_new;
reg init_we;
reg init_set;
reg next_reg;
reg next_new;
reg next_we;
reg next_set;
reg work_factor_reg;
reg work_factor_new;
reg work_factor_we;
reg [1 : 0] mode_reg;
reg [1 : 0] mode_new;
reg mode_we;
reg [31 : 0] work_factor_num_reg;
reg work_factor_num_we;
reg ready_reg;
reg [31 : 0] block_reg [0 : 31];
reg block_we;
reg [511 : 0] digest_reg;
reg digest_valid_reg;
//----------------------------------------------------------------
// Wires.
//----------------------------------------------------------------
wire core_ready;
wire [1023 : 0] core_block;
wire [511 : 0] core_digest;
wire core_digest_valid;
reg [4 : 0] block_addr;
reg state00_we;
reg state01_we;
reg state02_we;
reg state03_we;
reg state04_we;
reg state05_we;
reg state06_we;
reg state07_we;
reg state08_we;
reg state09_we;
reg state10_we;
reg state11_we;
reg state12_we;
reg state13_we;
reg state14_we;
reg state15_we;
reg [31 : 0] tmp_read_data;
reg tmp_error;
//----------------------------------------------------------------
// Concurrent connectivity for ports etc.
//----------------------------------------------------------------
assign core_block = {block_reg[00], block_reg[01], block_reg[02], block_reg[03],
block_reg[04], block_reg[05], block_reg[06], block_reg[07],
block_reg[08], block_reg[09], block_reg[10], block_reg[11],
block_reg[12], block_reg[13], block_reg[14], block_reg[15],
block_reg[16], block_reg[17], block_reg[18], block_reg[19],
block_reg[20], block_reg[21], block_reg[22], block_reg[23],
block_reg[24], block_reg[25], block_reg[26], block_reg[27],
block_reg[28], block_reg[29], block_reg[30], block_reg[31]};
assign read_data = tmp_read_data;
assign error = tmp_error;
//----------------------------------------------------------------
// core instantiation.
//----------------------------------------------------------------
sha512_core core(
.clk(clk),
.reset_n(reset_n),
.init(init_reg),
.next(next_reg),
.mode(mode_reg),
.work_factor(work_factor_reg),
.work_factor_num(work_factor_num_reg),
.block(core_block),
.ready(core_ready),
.state_wr_data(write_data),
.state00_we(state00_we),
.state01_we(state01_we),
.state02_we(state02_we),
.state03_we(state03_we),
.state04_we(state04_we),
.state05_we(state05_we),
.state06_we(state06_we),
.state07_we(state07_we),
.state08_we(state08_we),
.state09_we(state09_we),
.state10_we(state10_we),
.state11_we(state11_we),
.state12_we(state12_we),
.state13_we(state13_we),
.state14_we(state14_we),
.state15_we(state15_we),
.digest(core_digest),
.digest_valid(core_digest_valid)
);
//----------------------------------------------------------------
// reg_update
//
// Update functionality for all registers in the core.
// All registers are positive edge triggered with asynchronous
// active low reset. All registers have write enable.
//----------------------------------------------------------------
always @ (posedge clk or negedge reset_n)
begin : reg_update
integer i;
if (!reset_n)
begin
for (i = 0 ; i < 32 ; i = i + 1)
block_reg[i] <= 32'h0;
init_reg <= 1'h0;
next_reg <= 1'h0;
mode_reg <= MODE_SHA_512;
work_factor_reg <= 1'h0;
work_factor_num_reg <= DEFAULT_WORK_FACTOR_NUM;
ready_reg <= 1'h0;
digest_reg <= 512'h0;
digest_valid_reg <= 1'h0;
end
else
begin
ready_reg <= core_ready;
digest_valid_reg <= core_digest_valid;
init_reg <= init_new;
next_reg <= next_new;
if (mode_we)
mode_reg <= mode_new;
if (work_factor_we)
work_factor_reg <= work_factor_new;
if (work_factor_num_we)
work_factor_num_reg <= write_data;
if (core_digest_valid)
digest_reg <= core_digest;
if (block_we)
block_reg[block_addr] <= write_data;
end
end // reg_update
//----------------------------------------------------------------
// api_logic
//
// Implementation of the api logic. If cs is enabled will either
// try to write to or read from the internal registers.
//----------------------------------------------------------------
always @*
begin : api_logic
init_new = 1'h0;
next_new = 1'h0;
mode_new = MODE_SHA_512;
mode_we = 1'h0;
work_factor_new = 1'h0;
work_factor_we = 1'h0;
work_factor_num_we = 1'h0;
block_we = 1'h0;
state00_we = 1'h0;
state01_we = 1'h0;
state02_we = 1'h0;
state03_we = 1'h0;
state04_we = 1'h0;
state05_we = 1'h0;
state06_we = 1'h0;
state07_we = 1'h0;
state08_we = 1'h0;
state09_we = 1'h0;
state10_we = 1'h0;
state11_we = 1'h0;
state12_we = 1'h0;
state13_we = 1'h0;
state14_we = 1'h0;
state15_we = 1'h0;
tmp_read_data = 32'h00000000;
tmp_error = 1'h0;
block_addr = address[4 : 0] - ADDR_BLOCK0[4 : 0];
if (cs)
begin
if (we)
begin
if (core_ready)
begin
if ((address >= ADDR_BLOCK0) && (address <= ADDR_BLOCK31))
block_we = 1'h1;
case (address)
ADDR_CTRL:
begin
init_new = write_data[CTRL_INIT_BIT];
next_new = write_data[CTRL_NEXT_BIT];
mode_new = write_data[CTRL_MODE_HIGH_BIT : CTRL_MODE_LOW_BIT];
mode_we = 1'h1;
work_factor_new = write_data[CTRL_WORK_FACTOR_BIT];
work_factor_we = 1'h1;
end
ADDR_WORK_FACTOR_NUM:
begin
work_factor_num_we = 1;
end
ADDR_DIGEST0:
state00_we = 1;
ADDR_DIGEST1:
state01_we = 1;
ADDR_DIGEST2:
state02_we = 1;
ADDR_DIGEST3:
state03_we = 1;
ADDR_DIGEST4:
state04_we = 1;
ADDR_DIGEST5:
state05_we = 1;
ADDR_DIGEST6:
state06_we = 1;
ADDR_DIGEST7:
state07_we = 1;
ADDR_DIGEST8:
state08_we = 1;
ADDR_DIGEST9:
state09_we = 1;
ADDR_DIGEST10:
state10_we = 1;
ADDR_DIGEST11:
state11_we = 1;
ADDR_DIGEST12:
state12_we = 1;
ADDR_DIGEST13:
state13_we = 1;
ADDR_DIGEST14:
state14_we = 1;
ADDR_DIGEST15:
state15_we = 1;
default:
tmp_error = 1;
endcase // case (address)
end // if (core_ready)
end // if (we)
else
begin
if (core_ready)
if ((address >= ADDR_DIGEST0) && (address <= ADDR_DIGEST15))
tmp_read_data = digest_reg[(15 - (address - ADDR_DIGEST0)) * 32 +: 32];
if ((address >= ADDR_BLOCK0) && (address <= ADDR_BLOCK31))
tmp_read_data = block_reg[address[4 : 0]];
case (address)
ADDR_NAME0:
tmp_read_data = CORE_NAME0;
ADDR_NAME1:
tmp_read_data = CORE_NAME1;
ADDR_VERSION:
tmp_read_data = CORE_VERSION;
ADDR_CTRL:
tmp_read_data = {24'h000000, work_factor_reg, 3'b000, mode_reg, next_reg, init_reg};
ADDR_STATUS:
tmp_read_data = {28'h0000000, 2'b00, digest_valid_reg, ready_reg};
ADDR_WORK_FACTOR_NUM:
tmp_read_data = work_factor_num_reg;
default:
tmp_error = 1;
endcase // case (address)
end
end
end // addr_decoder
endmodule // sha512
//======================================================================
// EOF sha512.v
//======================================================================
|