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// FIXME ignores the AWIDTH (fifo size) parameter
module fifo_2clock
#(parameter WIDTH=36, SIZE=6)
(input wclk, input [WIDTH-1:0] datain, input src_rdy_i, output dst_rdy_o, output [15:0] space,
input rclk, output [WIDTH-1:0] dataout, output src_rdy_o, input dst_rdy_i, output [15:0] occupied,
input arst);
wire [SIZE:0] level_rclk, level_wclk; // xilinx adds an extra bit if you ask for accurate levels
wire full, empty, write, read;
assign dst_rdy_o = ~full;
assign src_rdy_o = ~empty;
assign write = src_rdy_i & dst_rdy_o;
assign read = src_rdy_o & dst_rdy_i;
generate
if(WIDTH==36)
if(SIZE==9)
fifo_xlnx_512x36_2clk fifo_xlnx_512x36_2clk
(.rst(arst),
.wr_clk(wclk),.din(datain),.full(full),.wr_en(write),.wr_data_count(level_wclk),
.rd_clk(rclk),.dout(dataout),.empty(empty),.rd_en(read),.rd_data_count(level_rclk) );
else if(SIZE==11)
fifo_xlnx_2Kx36_2clk fifo_xlnx_2Kx36_2clk
(.rst(arst),
.wr_clk(wclk),.din(datain),.full(full),.wr_en(write),.wr_data_count(level_wclk),
.rd_clk(rclk),.dout(dataout),.empty(empty),.rd_en(read),.rd_data_count(level_rclk) );
else if(SIZE==6)
fifo_xlnx_64x36_2clk fifo_xlnx_64x36_2clk
(.rst(arst),
.wr_clk(wclk),.din(datain),.full(full),.wr_en(write),.wr_data_count(level_wclk),
.rd_clk(rclk),.dout(dataout),.empty(empty),.rd_en(read),.rd_data_count(level_rclk) );
else
fifo_xlnx_512x36_2clk fifo_xlnx_512x36_2clk
(.rst(arst),
.wr_clk(wclk),.din(datain),.full(full),.wr_en(write),.wr_data_count(level_wclk),
.rd_clk(rclk),.dout(dataout),.empty(empty),.rd_en(read),.rd_data_count(level_rclk) );
else if((WIDTH==19)|(WIDTH==18))
if(SIZE==4)
fifo_xlnx_16x19_2clk fifo_xlnx_16x19_2clk
(.rst(arst),
.wr_clk(wclk),.din(datain),.full(full),.wr_en(write),.wr_data_count(level_wclk),
.rd_clk(rclk),.dout(dataout),.empty(empty),.rd_en(read),.rd_data_count(level_rclk) );
endgenerate
assign occupied = {{(16-SIZE-1){1'b0}},level_rclk};
assign space = ((1<<SIZE)+1)-level_wclk;
endmodule // fifo_2clock
/*
`else
// ISE sucks, so the following doesn't work properly
reg [AWIDTH-1:0] wr_addr, rd_addr;
wire [AWIDTH-1:0] wr_addr_rclk, rd_addr_wclk;
wire [AWIDTH-1:0] next_rd_addr;
wire enb_read;
// Write side management
wire [AWIDTH-1:0] next_wr_addr = wr_addr + 1;
always @(posedge wclk or posedge arst)
if(arst)
wr_addr <= 0;
else if(write)
wr_addr <= next_wr_addr;
assign full = (next_wr_addr == rd_addr_wclk);
// RAM for data storage. Data out is registered, complicating the
// read side logic
ram_2port #(.DWIDTH(DWIDTH),.AWIDTH(AWIDTH)) mac_rx_ff_ram
(.clka(wclk),.ena(1'b1),.wea(write),.addra(wr_addr),.dia(datain),.doa(),
.clkb(rclk),.enb(enb_read),.web(1'b0),.addrb(next_rd_addr),.dib(0),.dob(dataout) );
// Read side management
reg data_valid;
assign empty = ~data_valid;
assign next_rd_addr = rd_addr + data_valid;
assign enb_read = read | ~data_valid;
always @(posedge rclk or posedge arst)
if(arst)
rd_addr <= 0;
else if(read)
rd_addr <= rd_addr + 1;
always @(posedge rclk or posedge arst)
if(arst)
data_valid <= 0;
else
if(read & (next_rd_addr == wr_addr_rclk))
data_valid <= 0;
else if(next_rd_addr != wr_addr_rclk)
data_valid <= 1;
// Send pointers across clock domains via gray code
gray_send #(.WIDTH(AWIDTH)) send_wr_addr
(.clk_in(wclk),.addr_in(wr_addr),
.clk_out(rclk),.addr_out(wr_addr_rclk) );
gray_send #(.WIDTH(AWIDTH)) send_rd_addr
(.clk_in(rclk),.addr_in(rd_addr),
.clk_out(wclk),.addr_out(rd_addr_wclk) );
// Generate fullness info, these are approximate and may be delayed
// and are only for higher-level flow control.
// Only full and empty are guaranteed exact.
always @(posedge wclk)
level_wclk <= wr_addr - rd_addr_wclk;
always @(posedge rclk)
level_rclk <= wr_addr_rclk - rd_addr;
`endif
endmodule // fifo_2clock
*/
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