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// SERDES Interface
// LS-Byte is sent first, MS-Byte is second
// Invalid K Codes
// K0.0 000-00000 Error detected
// K31.7 111-11111 Loss of input signal
// Valid K Codes
// K28.0 000-11100
// K28.1 001-11100 Alternate COMMA?
// K28.2 010-11100
// K28.3 011-11100
// K28.4 100-11100
// K28.5 101-11100 Standard COMMA?
// K28.6 110-11100
// K28.7 111-11100 Bad COMMA?
// K23.7 111-10111
// K27.7 111-11011
// K29.7 111-11101
// K30.7 111-11110
module serdes_tx
#(parameter FIFOSIZE = 9)
(input clk,
input rst,
// TX HW Interface
output ser_tx_clk,
output reg [15:0] ser_t,
output reg ser_tklsb,
output reg ser_tkmsb,
// TX Stream Interface
input [31:0] rd_dat_i,
input [3:0] rd_flags_i,
output rd_ready_o,
input rd_ready_i,
// Flow control interface
input inhibit_tx,
input send_xon,
input send_xoff,
output sent,
// FIFO Levels
output [15:0] fifo_occupied,
output fifo_full,
output fifo_empty,
// DEBUG
output [31:0] debug
);
localparam K_COMMA = 8'b101_11100; // 0xBC K28.5
localparam K_IDLE = 8'b001_11100; // 0x3C K28.1
localparam K_PKT_START = 8'b110_11100; // 0xDC K28.6
localparam K_PKT_END = 8'b100_11100; // 0x9C K28.4
localparam K_XON = 8'b010_11100; // 0x5C K28.2
localparam K_XOFF = 8'b011_11100; // 0x7C K28.3
localparam K_LOS = 8'b111_11111; // 0xFF K31.7
localparam K_ERROR = 8'b000_00000; // 0x00 K00.0
localparam D_56 = 8'b110_00101; // 0xC5 D05.6
assign ser_tx_clk = clk;
localparam IDLE = 3'd0;
localparam RUN1 = 3'd1;
localparam RUN2 = 3'd2;
localparam DONE = 3'd3;
localparam SENDCRC = 3'd4;
localparam WAIT = 3'd5;
reg [2:0] state;
reg [15:0] CRC;
wire [15:0] nextCRC;
reg [3:0] wait_count;
// Internal FIFO, size 9 is 2K, size 10 is 4K bytes
wire sop_o, eop_o;
wire [31:0] data_o;
wire rd_sop_i = rd_flags_i[0];
wire rd_eop_i = rd_flags_i[1];
wire [1:0] rd_occ_i = rd_flags_i[3:2]; // Unused
wire have_data, empty, read;
fifo_cascade #(.WIDTH(34),.SIZE(FIFOSIZE)) serdes_tx_fifo
(.clk(clk),.reset(rst),.clear(0),
.datain({rd_sop_i,rd_eop_i,rd_dat_i}), .src_rdy_i(rd_ready_i), .dst_rdy_o(rd_ready_o),
.dataout({sop_o,eop_o,data_o}), .dst_rdy_i(read), .src_rdy_o(have_data),
.space(), .occupied(fifo_occupied) );
assign fifo_full = ~rd_ready_o;
assign empty = ~have_data;
assign fifo_empty = empty;
// FIXME Implement flow control
reg [15:0] second_word;
reg [33:0] pipeline;
assign read = (~send_xon & ~send_xoff & (state==RUN2)) | ((state==IDLE) & ~empty & ~sop_o);
assign sent = send_xon | send_xoff;
// 2nd half of above probably not necessary. Just in case we get junk between packets
always @(posedge clk)
if(rst)
begin
state <= IDLE;
wait_count <= 0;
{ser_tkmsb,ser_tklsb,ser_t} <= 18'd0;
//{2'b10,K_COMMA,K_COMMA};
// make tkmsb and tklsb different so they can go in IOFFs
end
else
if(send_xon)
{ser_tkmsb,ser_tklsb,ser_t} <= {2'b11,K_XON,K_XON};
else if(send_xoff)
{ser_tkmsb,ser_tklsb,ser_t} <= {2'b11,K_XOFF,K_XOFF};
else
case(state)
IDLE :
begin
if(sop_o & ~empty & ~inhibit_tx)
begin
{ser_tkmsb,ser_tklsb,ser_t} <= {2'b11,K_PKT_START,K_PKT_START};
state <= RUN1;
end
else
{ser_tkmsb,ser_tklsb,ser_t} <= {2'b10,K_COMMA,D_56};
end
RUN1 :
begin
if(empty | inhibit_tx)
{ser_tkmsb,ser_tklsb,ser_t} <= {2'b10,K_COMMA,D_56};
else
begin
{ser_tkmsb,ser_tklsb,ser_t} <= {2'b00,data_o[15:0]};
state <= RUN2;
end
end
RUN2 :
begin
{ser_tkmsb,ser_tklsb,ser_t} <= {2'b00,data_o[31:16]};
if(eop_o)
state <= DONE;
else
state <= RUN1;
end
DONE :
begin
{ser_tkmsb,ser_tklsb,ser_t} <= {2'b11,K_PKT_END,K_PKT_END};
state <= SENDCRC;
end
SENDCRC :
begin
{ser_tkmsb,ser_tklsb,ser_t} <= {2'b00,CRC};
state <= WAIT;
wait_count <= 4'd15;
end
WAIT :
begin
{ser_tkmsb,ser_tklsb,ser_t} <= {2'b10,K_COMMA,D_56};
if(wait_count == 0)
state <= IDLE;
else
wait_count <= wait_count - 1;
end
default
state <= IDLE;
endcase // case(state)
always @(posedge clk)
if(rst)
CRC <= 16'hFFFF;
else if(state == IDLE)
CRC <= 16'hFFFF;
else if( (~empty & ~inhibit_tx & (state==RUN1)) || (state==RUN2) )
CRC <= nextCRC;
CRC16_D16 crc_blk( (state==RUN1) ? data_o[15:0] : data_o[31:16], CRC, nextCRC);
assign debug = { 28'd0, state[2:0] };
endmodule // serdes_tx
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