//======================================================================
//
// trng_csprng_fifo.v
// ------------------
// Output FIFO for the CSPRNG in the TRNG.
//
//
// Author: Joachim Strombergson
// Copyright (c) 2014, SUNET
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or
// without modification, are permitted provided that the following
// conditions are met:
//
// 1. Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//
// 2. 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.
//
// 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 OWNER 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 trng_csprng_fifo(
// Clock and reset.
input wire clk,
input wire reset_n,
input wire [511 : 0] csprng_data,
input wire csprng_data_valid,
input wire discard,
output wire more_data,
output wire rnd_syn,
output wire [31 : 0] rnd_data,
input wire rnd_ack
);
//----------------------------------------------------------------
// Internal constant and parameter definitions.
//----------------------------------------------------------------
localparam FIFO_ADDR_BITS = 2;
localparam FIFO_ADDR_MAX = FIFO_ADDR_BITS - 1;
localparam FIFO_MAX = (2 ** FIFO_ADDR_BITS) - 1;
localparam WR_IDLE = 0;
localparam WR_WAIT = 1;
localparam WR_WRITE = 2;
localparam WR_DISCARD = 7;
localparam RD_IDLE = 0;
localparam RD_ACK = 1;
localparam RD_DISCARD = 7;
//----------------------------------------------------------------
// Registers including update variables and write enable.
//----------------------------------------------------------------
reg [511 : 0] fifo_mem [0 : FIFO_MAX];
reg fifo_mem_we;
reg [3 : 0] mux_data_ptr_reg;
reg [3 : 0] mux_data_ptr_new;
reg mux_data_ptr_inc;
reg mux_data_ptr_rst;
reg mux_data_ptr_we;
reg [FIFO_ADDR_MAX : 0] rd_ptr_reg;
reg [FIFO_ADDR_MAX : 0] rd_ptr_new;
reg rd_ptr_inc;
reg rd_ptr_rst;
reg rd_ptr_we;
reg [FIFO_ADDR_MAX : 0] wr_ptr_reg;
reg [FIFO_ADDR_MAX : 0] wr_ptr_new;
reg wr_ptr_inc;
reg wr_ptr_rst;
reg wr_ptr_we;
reg [FIFO_ADDR_MAX : 0] fifo_ctr_reg;
reg [FIFO_ADDR_MAX : 0] fifo_ctr_new;
reg fifo_ctr_inc;
reg fifo_ctr_dec;
reg fifo_ctr_rst;
reg fifo_ctr_we;
reg fifo_empty;
reg fifo_full;
reg [31 : 0] rnd_data_reg;
reg rnd_syn_reg;
reg rnd_syn_new;
reg rnd_syn_we;
reg [2 : 0] rd_ctrl_reg;
reg [2 : 0] rd_ctrl_new;
reg rd_ctrl_we;
reg [2 : 0] wr_ctrl_reg;
reg [2 : 0] wr_ctrl_new;
reg wr_ctrl_we;
reg more_data_reg;
reg more_data_new;
//----------------------------------------------------------------
// Wires.
//----------------------------------------------------------------
reg [31 : 0] muxed_data;
//----------------------------------------------------------------
// Concurrent connectivity for ports etc.
//----------------------------------------------------------------
assign rnd_data = rnd_data_reg;
assign rnd_syn = rnd_syn_reg;
assign more_data = more_data_reg;
//----------------------------------------------------------------
// reg_update
//
// Register update. All registers have asynchronous reset.
//----------------------------------------------------------------
always @ (posedge clk or negedge reset_n)
begin
if (!reset_n)
begin
fifo_mem[00] <= {16{32'h00000000}};
fifo_mem[01] <= {16{32'h00000000}};
fifo_mem[02] <= {16{32'h00000000}};
fifo_mem[03] <= {16{32'h00000000}};
mux_data_ptr_reg <= 4'h0;
rd_ptr_reg <= {FIFO_ADDR_BITS{1'b0}};
wr_ptr_reg <= {FIFO_ADDR_BITS{1'b0}};
fifo_ctr_reg <= {FIFO_ADDR_BITS{1'b0}};
rnd_data_reg <= 32'h00000000;
rnd_syn_reg <= 0;
more_data_reg <= 0;
wr_ctrl_reg <= WR_IDLE;
rd_ctrl_reg <= RD_IDLE;
end
else
begin
rnd_data_reg <= muxed_data;
more_data_reg <= more_data_new;
if (rnd_syn_we)
begin
rnd_syn_reg <= rnd_syn_new;
end
if (fifo_mem_we)
begin
fifo_mem[wr_ptr_reg] <= csprng_data;
end
if (mux_data_ptr_we)
begin
mux_data_ptr_reg <= mux_data_ptr_new;
end
if (rd_ptr_we)
begin
rd_ptr_reg <= rd_ptr_new;
end
if (wr_ptr_we)
begin
wr_ptr_reg <= wr_ptr_new;
end
if (fifo_ctr_we)
begin
fifo_ctr_reg <= fifo_ctr_new;
end
if (rd_ctrl_we)
begin
rd_ctrl_reg <= rd_ctrl_new;
end
if (wr_ctrl_we)
begin
wr_ctrl_reg <= wr_ctrl_new;
end
end
end // reg_update
//----------------------------------------------------------------
// output_data_mux
//
// Logic that reads out a 512 bit word from the fifo memory
// and then selects a 32-bit word as output data.
//----------------------------------------------------------------
always @*
begin : output_data_mux
reg [511 : 0] fifo_rd_data;
fifo_rd_data = fifo_mem[rd_ptr_reg];
muxed_data = fifo_rd_data[mux_data_ptr_reg * 32 +: 32];
end // output_data_mux
//----------------------------------------------------------------
// mux_data_ptr
//
// Pointer for selecting output data word from the 512 bit
// word currently being read in the FIFO.
//----------------------------------------------------------------
always @*
begin : mux_data_ptr
mux_data_ptr_new = 4'h0;
mux_data_ptr_we = 0;
if (mux_data_ptr_rst)
begin
mux_data_ptr_new = 4'h0;
mux_data_ptr_we = 1;
end
if (mux_data_ptr_inc)
begin
mux_data_ptr_new = mux_data_ptr_reg + 1'b1;
mux_data_ptr_we = 1;
end
end // mux_data_ptr
//----------------------------------------------------------------
// fifo_rd_ptr
//
// Pointer that selects the current 512 bit word in the FIFO
// to extract data from.
//----------------------------------------------------------------
always @*
begin : fifo_rd_ptr
rd_ptr_new = {FIFO_ADDR_BITS{1'b0}};
rd_ptr_we = 0;
fifo_ctr_dec = 0;
if (rd_ptr_rst)
rd_ptr_we = 1;
if (rd_ptr_inc)
begin
fifo_ctr_dec = 1;
if (rd_ptr_reg == FIFO_MAX)
rd_ptr_we = 1;
else
begin
rd_ptr_new = rd_ptr_reg + 1'b1;
rd_ptr_we = 1;
end
end
end // fifo_rd_ptr
//----------------------------------------------------------------
// fifo_wr_ptr
//
// Pointer to where to store a new 512 bit word in the FIFO.
//----------------------------------------------------------------
always @*
begin : fifo_wr_ptr
wr_ptr_new = {FIFO_ADDR_BITS{1'b0}};
wr_ptr_we = 0;
if (wr_ptr_rst)
wr_ptr_we = 1;
if (wr_ptr_inc)
begin
if (wr_ptr_reg == FIFO_MAX)
wr_ptr_we = 1;
else
begin
wr_ptr_new = wr_ptr_reg + 1'b1;
wr_ptr_we = 1;
end
end
end // fifo_wr_ptr
//----------------------------------------------------------------
// fifo_ctr
//
// fifo counter tracks the number of 512 bit elements currently
// in the fifp. The counter also signals the csprng when more
// data is needed. The fifo also signals applications when
// random numbers are available, that is there is at least
// one elemnt in the fifo with 32-bit words not yet used.
//----------------------------------------------------------------
always @*
begin : fifo_ctr
fifo_ctr_new = {FIFO_ADDR_BITS{1'b0}};
fifo_ctr_we = 0;
fifo_empty = 0;
fifo_full = 0;
if (fifo_ctr_reg == 0)
begin
fifo_empty = 1;
end
if (fifo_ctr_reg == FIFO_MAX)
begin
fifo_full = 1;
end
if (fifo_ctr_rst)
fifo_ctr_we = 1;
if ((fifo_ctr_inc) && (fifo_ctr_reg < FIFO_MAX))
begin
fifo_ctr_new = fifo_ctr_reg + 1'b1;
fifo_ctr_we = 1;
end
if ((fifo_ctr_dec) && (fifo_ctr_reg > 0))
begin
fifo_ctr_new = fifo_ctr_reg - 1'b1;
fifo_ctr_we = 1;
end
end // fifo_ctr
//----------------------------------------------------------------
// rd_ctrl
//
// Control FSM for reading data as requested by the consumers.
//----------------------------------------------------------------
always @*
begin : rd_ctrl
mux_data_ptr_rst = 0;
mux_data_ptr_inc = 0;
rnd_syn_new = 0;
rnd_syn_we = 0;
rd_ptr_inc = 0;
rd_ptr_rst = 0;
rd_ctrl_new = RD_IDLE;
rd_ctrl_we = 0;
case (rd_ctrl_reg)
RD_IDLE:
begin
if (discard)
begin
rd_ctrl_new = RD_DISCARD;
rd_ctrl_we = 1;
end
else
begin
if (!fifo_empty)
begin
rnd_syn_new = 1;
rnd_syn_we = 1;
rd_ctrl_new = RD_ACK;
rd_ctrl_we = 1;
end
end
end
RD_ACK:
begin
if (discard)
begin
rd_ctrl_new = RD_DISCARD;
rd_ctrl_we = 1;
end
else
begin
if (rnd_ack)
begin
if (mux_data_ptr_reg == 4'hf)
begin
rd_ptr_inc = 1;
mux_data_ptr_rst = 1;
end
else
begin
mux_data_ptr_inc = 1;
end
rnd_syn_new = 0;
rnd_syn_we = 1;
rd_ctrl_new = RD_IDLE;
rd_ctrl_we = 1;
end
end
end
RD_DISCARD:
begin
rnd_syn_new = 0;
rnd_syn_we = 1;
rd_ptr_rst = 1;
rd_ctrl_new = RD_IDLE;
rd_ctrl_we = 1;
end
endcase // case (rd_ctrl_reg)
end // rd_ctrl
//----------------------------------------------------------------
// wr_ctrl
//
// FSM for requesting data and writing new data to the fifo.
//----------------------------------------------------------------
always @*
begin : wr_ctrl
wr_ptr_inc = 0;
wr_ptr_rst = 0;
fifo_mem_we = 0;
fifo_ctr_inc = 0;
fifo_ctr_rst = 0;
more_data_new = 0;
wr_ctrl_new = WR_IDLE;
wr_ctrl_we = 0;
case (wr_ctrl_reg)
WR_IDLE:
begin
if (discard)
begin
wr_ctrl_new = WR_DISCARD;
wr_ctrl_we = 1;
end
else
begin
if (!fifo_full)
begin
more_data_new = 1;
end
if (csprng_data_valid)
begin
fifo_mem_we = 1;
wr_ptr_inc = 1;
fifo_ctr_inc = 1;
end
end
end
WR_DISCARD:
begin
fifo_ctr_rst = 1;
wr_ptr_rst = 1;
wr_ctrl_new = WR_IDLE;
wr_ctrl_we = 1;
end
endcase // case (wr_ctrl_reg)
end // wr_ctrl
endmodule // trng_csprng_fifo
//======================================================================
// EOF trng_csprng_fifo.v
//======================================================================