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//
// Copyright 2011-2012 Ettus Research LLC
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
//
module vita_tx_deframer
#(parameter BASE=0,
parameter MAXCHAN=1,
parameter USE_TRANS_HEADER=0)
(input clk, input reset, input clear, input clear_seqnum,
input set_stb, input [7:0] set_addr, input [31:0] set_data,
// To FIFO interface of Buffer Pool
input [35:0] data_i,
input src_rdy_i,
output dst_rdy_o,
output [5+64+16+(32*MAXCHAN)-1:0] sample_fifo_o,
output sample_fifo_src_rdy_o,
input sample_fifo_dst_rdy_i,
output [31:0] current_seqnum,
// FIFO Levels
output [15:0] fifo_occupied,
output fifo_full,
output fifo_empty,
output [31:0] debug
);
localparam FIFOWIDTH = 5+64+16+(32*MAXCHAN);
wire [1:0] numchan = 0;/*
setting_reg #(.my_addr(BASE), .at_reset(0), .width(2)) sr_numchan
(.clk(clk),.rst(reset),.strobe(set_stb),.addr(set_addr),
.in(set_data),.out(numchan),.changed());
*/
reg [3:0] vita_state;
wire has_streamid, has_classid, has_secs, has_tics, has_trailer;
assign has_streamid = (data_i[31:28]==4'b0001);
assign has_classid = data_i[27];
assign has_secs = ~(data_i[23:22]==2'b00);
assign has_tics = ~(data_i[21:20]==2'b00);
assign has_trailer = data_i[26];
wire is_sob = data_i[25];
wire is_eob = data_i[24];
wire eof = data_i[33];
reg has_streamid_reg, has_classid_reg, has_secs_reg, has_tics_reg;
reg has_trailer_reg, is_sob_reg, is_eob_reg;
reg [15:0] pkt_len;
reg [1:0] vector_phase;
wire line_done;
wire [31:0] seqnum = data_i;
reg [31:0] seqnum_reg;
wire [31:0] next_seqnum = seqnum_reg + 32'd1;
wire [3:0] vita_seqnum = data_i[19:16];
reg [3:0] vita_seqnum_reg;
wire [3:0] next_vita_seqnum = vita_seqnum_reg[3:0] + 4'd1;
reg seqnum_err;
assign current_seqnum = seqnum_reg;
// Output FIFO for packetized data
localparam VITA_TRANS_HEADER = 0;
localparam VITA_HEADER = 1;
localparam VITA_STREAMID = 2;
localparam VITA_CLASSID = 3;
localparam VITA_CLASSID2 = 4;
localparam VITA_SECS = 5;
localparam VITA_TICS = 6;
localparam VITA_TICS2 = 7;
localparam VITA_PAYLOAD = 8;
localparam VITA_TRAILER = 10;
localparam VITA_DUMP = 11;
wire [15:0] hdr_len = 2 + has_streamid_reg + has_classid_reg + has_classid_reg + has_secs_reg +
has_tics_reg + has_tics_reg + has_trailer_reg;
wire vita_eof = (pkt_len==hdr_len);
wire eop = eof | vita_eof; // FIXME would ignoring eof allow larger VITA packets?
wire fifo_space;
always @(posedge clk)
if(reset | clear | clear_seqnum)
begin
seqnum_reg <= 32'hFFFF_FFFF;
vita_seqnum_reg <= 4'hF;
end
else
begin
if((vita_state==VITA_TRANS_HEADER) & src_rdy_i)
seqnum_reg <= seqnum;
if((vita_state==VITA_HEADER) & src_rdy_i)
vita_seqnum_reg <= vita_seqnum;
end // else: !if(reset | clear_seqnum)
always @(posedge clk)
if(reset | clear)
begin
vita_state <= (USE_TRANS_HEADER==1) ? VITA_TRANS_HEADER : VITA_HEADER;
{has_streamid_reg, has_classid_reg, has_secs_reg, has_tics_reg, has_trailer_reg, is_sob_reg, is_eob_reg}
<= 0;
seqnum_err <= 0;
end
else if(src_rdy_i & dst_rdy_o) begin //valid read
case(vita_state)
VITA_TRANS_HEADER :
begin
seqnum_err <= ~(seqnum == next_seqnum);
vita_state <= VITA_HEADER;
end
VITA_HEADER :
begin
{has_streamid_reg, has_classid_reg, has_secs_reg, has_tics_reg, has_trailer_reg, is_sob_reg, is_eob_reg}
<= {has_streamid, has_classid, has_secs, has_tics, has_trailer, is_sob, is_eob};
pkt_len <= data_i[15:0];
vector_phase <= 0;
if(has_streamid)
vita_state <= VITA_STREAMID;
else if(has_classid)
vita_state <= VITA_CLASSID;
else if(has_secs)
vita_state <= VITA_SECS;
else if(has_tics)
vita_state <= VITA_TICS;
else
vita_state <= VITA_PAYLOAD;
seqnum_err <= seqnum_err | ~(vita_seqnum == next_vita_seqnum);
end // case: VITA_HEADER
VITA_STREAMID :
if(has_classid_reg)
vita_state <= VITA_CLASSID;
else if(has_secs_reg)
vita_state <= VITA_SECS;
else if(has_tics_reg)
vita_state <= VITA_TICS;
else
vita_state <= VITA_PAYLOAD;
VITA_CLASSID :
vita_state <= VITA_CLASSID2;
VITA_CLASSID2 :
if(has_secs_reg)
vita_state <= VITA_SECS;
else if(has_tics_reg)
vita_state <= VITA_TICS;
else
vita_state <= VITA_PAYLOAD;
VITA_SECS :
if(has_tics_reg)
vita_state <= VITA_TICS;
else
vita_state <= VITA_PAYLOAD;
VITA_TICS :
vita_state <= VITA_TICS2;
VITA_TICS2 :
vita_state <= VITA_PAYLOAD;
VITA_PAYLOAD : begin
//step through each element until line done, then reset
vector_phase <= (line_done)? 0: vector_phase + 1;
//decrement the packet count after each line
pkt_len <= (line_done)? pkt_len - 1 : pkt_len;
//end of frame reached, determine next state
//otherwise, keep processing through the payload
if (line_done && vita_eof) begin
if (eof) begin
vita_state <= (USE_TRANS_HEADER==1) ? VITA_TRANS_HEADER : VITA_HEADER;
end
else if (has_trailer_reg) begin
vita_state <= VITA_TRAILER;
end
else begin
vita_state <= VITA_DUMP;
end
end //line_done && vita_eof
end //end VITA_PAYLOAD
VITA_TRAILER :
if(eof)
vita_state <= (USE_TRANS_HEADER==1) ? VITA_TRANS_HEADER : VITA_HEADER;
else
vita_state <= VITA_DUMP;
VITA_DUMP :
if(eof)
vita_state <= (USE_TRANS_HEADER==1) ? VITA_TRANS_HEADER : VITA_HEADER;
default :
vita_state <= (USE_TRANS_HEADER==1) ? VITA_TRANS_HEADER : VITA_HEADER;
endcase // case (vita_state)
end //valid read
assign line_done = (MAXCHAN == 1)? 1 : (vector_phase == numchan);
wire [FIFOWIDTH-1:0] fifo_i;
reg [63:0] send_time;
always @(posedge clk)
case(vita_state)
VITA_TICS :
send_time[63:32] <= data_i[31:0];
VITA_TICS2 :
send_time[31:0] <= data_i[31:0];
endcase // case (vita_state)
//sample registers for de-framing a vector input
reg [31:0] sample_reg [1:0];
always @(posedge clk)
if(src_rdy_i && dst_rdy_o)
sample_reg[vector_phase] <= data_i[31:0];
wire store = (vita_state == VITA_PAYLOAD)? (src_rdy_i && line_done) : 0;
assign dst_rdy_o = (vita_state == VITA_PAYLOAD)? fifo_space : 1;
fifo_short #(.WIDTH(FIFOWIDTH)) short_tx_q
(.clk(clk), .reset(reset), .clear(clear),
.datain(fifo_i), .src_rdy_i(store), .dst_rdy_o(fifo_space),
.dataout(sample_fifo_o), .src_rdy_o(sample_fifo_src_rdy_o), .dst_rdy_i(sample_fifo_dst_rdy_i) );
//assign registered/live data to the samples vector
//the numchan'th sample vector is muxed to live data
wire [(32*MAXCHAN)-1:0] samples;
generate
genvar i;
for (i=0; i < MAXCHAN; i = i +1) begin : assign_samples
wire live_data = (i == (MAXCHAN-1))? 1 : numchan == i;
assign samples[32*i + 31:32*i] = (live_data)? data_i[31:0] : sample_reg[i];
end
endgenerate
// sob, eob, has_tics (send_at) ignored on all lines except first
assign fifo_i = {samples,seqnum_err,has_tics_reg,is_sob_reg,is_eob_reg,eop,
12'd0,seqnum_reg[3:0],send_time};
assign debug = { { 8'b0 },
{ 8'b0 },
{ eof, line_done, store, fifo_space, src_rdy_i, dst_rdy_o, vector_phase[1:0] },
{ has_secs_reg, is_sob_reg, is_eob_reg, eop, vita_state[3:0] } };
endmodule // vita_tx_deframer
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