ship: Debug
== Ports ===========================================================
-data in: in
+data in: in
+dockless out: out
+
+percolate down: uart_in 1
+percolate up: uart_out 1
+percolate up: rst_out 1
+percolate down: rst_in 1
== Constants ========================================================
== TeX ==============================================================
+percolate up: uart_rts 1
+percolate down: uart_cts 1
+
This ship is used for debugging. It has only one port, {\tt in}.
Programmers should send debug report values to this port. How such
values are reported back to the programmer doing the debugging is left
== FPGA ==============================================================
- reg [`WORDWIDTH-1:0] out_d;
- assign out_d_ = out_d;
-
- always @(posedge clk) begin
- if (!rst) begin
- `reset
- end else begin
- `flush
- `cleanup
- if (`in_full && `out_empty) begin
- `drain_in
- `fill_out
- out_d <= in_d;
- end
+ wire break_i;
+ reg send_k;
+ initial send_k = 0;
+
+ reg [`WORDWIDTH-1:0] data_to_host_full_word;
+ reg [7:0] count_in;
+ reg [7:0] count_out;
+ reg [49:0] out_d;
+ assign out_d_ = out_d;
+
+ wire data_to_host_full;
+ reg [7:0] data_to_host;
+ wire data_to_fleet_empty;
+ wire [7:0] data_to_fleet;
+ reg data_to_host_write_enable;
+ reg data_to_fleet_read_enable;
+ reg [7:0] force_reset;
+
+ wire sio_ce;
+ wire sio_ce_x4;
+
+ wire break;
+ wire uart_cts;
+ assign uart_cts = 0;
+ assign rst_out = rst_in || (force_reset!=0) || break;
+
+ // fst=3 means clock divider is 3+2=5 for a 50Mhz clock => 10Mhz
+ // using a 33Mhz clock,
+ // 33.333Mhz / 38400hz * 4 = 217.013 => 215+2,1 => 215,1
+ // using a 100Mhz clock,
+ // 100Mhz / 38400hz * 4 = 651.039 => 215+2,3 => 215,3
+ sasc_brg sasc_brg(clk, !rst_in, 215, 3, sio_ce, sio_ce_x4);
+ sasc_top sasc_top(clk, !rst_in,
+ uart_in,
+ uart_out,
+ uart_cts,
+ uart_rts,
+ sio_ce,
+ sio_ce_x4,
+ data_to_host,
+ data_to_fleet,
+ data_to_fleet_read_enable,
+ data_to_host_write_enable,
+ data_to_host_full,
+ data_to_fleet_empty,
+ break,
+ break_i);
+
+ reg [16:0] credits;
+
+ // fpga -> host
+ always @(posedge clk) begin
+ if (rst_in || break) begin
+ count_in <= 0;
+ count_out <= 0;
+ force_reset <= 0;
+ credits = 0;
+ `reset
+ end else begin
+
+ `cleanup
+
+ // fpga -> host
+ data_to_host_write_enable <= 0;
+ if (force_reset == 1) begin
+ force_reset <= 0;
+ data_to_host_write_enable <= 1;
+ credits = 0;
+ count_in <= 0;
+ count_out <= 0;
+ `reset
+ end else if (force_reset != 0) begin
+ force_reset <= force_reset-1;
+ end else if (count_out==0 && `in_full) begin
+ `drain_in
+ data_to_host_full_word <= in_d;
+ count_out <= 8;
+ end else if (count_out!=0 && !data_to_host_full && !data_to_host_write_enable && credits!=0) begin
+ data_to_host <= { 2'b0, data_to_host_full_word[5:0] };
+ data_to_host_full_word <= (data_to_host_full_word >> 6);
+ data_to_host_write_enable <= 1;
+ count_out <= count_out-1;
+ credits = credits - 1;
+ end
+
+ // host -> fpga
+ data_to_fleet_read_enable <= 0;
+ if (!data_to_fleet_empty && !data_to_fleet_read_enable) begin
+
+ // Note: if the switch fabric refuses to accept a new item,
+ // we can get deadlocked in a state where sending a reset
+ // code (2'b11) won't have any effect. Probably need to go
+ // back to using the break signal.
+
+ // command 0: data
+ if (data_to_fleet[7:6] == 2'b00 && `out_empty) begin
+ data_to_fleet_read_enable <= 1;
+ out_d <= { out_d[43:0], data_to_fleet[5:0] };
+ if (count_in==9) begin
+ count_in <= 0;
+ `fill_out
+ end else begin
+ count_in <= count_in+1;
+ end
+
+ // command 1: flow control credit
+ end else if (data_to_fleet[7:6] == 2'b01) begin
+ data_to_fleet_read_enable <= 1;
+ credits = credits + data_to_fleet[5:0];
+
+/*
+ // uncommenting this requires changing data_to_host_write_enable
+ // to a blocking assignment, and seems to cause data loss whenever
+ // more than four items are in flight.
+ // command 2: echo
+ end else if (data_to_fleet[7:6] == 2'b10 && !data_to_host_full && !data_to_host_write_enable) begin
+ data_to_fleet_read_enable <= 1;
+ data_to_host <= data_to_fleet;
+ data_to_host_write_enable = 1;
+*/
+
+ // command 3: reset (and echo back reset code)
+ end else if (data_to_fleet[7:6] == 2'b11) begin
+ data_to_fleet_read_enable <= 1;
+ data_to_host <= data_to_fleet;
+ force_reset <= 255;
+
+ end
+
+ end
+
end
end
+== UCF =================================================================
+
+Net clk_pin LOC=AH15;
+Net clk_pin PERIOD = 10 ns HIGH 50%; # 100Mhz
+
+# 33mhz clock
+#Net clk_pin LOC=AH17;
+#Net clk_pin TNM_NET = clk_pin;
+#TIMESPEC TS_clk_pin = PERIOD clk_pin 30 ns HIGH 50%; # 33Mhz
+
+Net rst_pin LOC=E9;
+Net rst_pin PULLUP;
+Net rst_pin TIG;
+
+#Net uart_cts LOC=G6;
+#Net uart_cts IOSTANDARD = LVCMOS33;
+#Net uart_cts TIG;
+
+#Net uart_rts LOC=F6;
+#Net uart_rts IOSTANDARD = LVCMOS33;
+#Net uart_rts TIG;
+
+Net uart_in LOC=AG15;
+#Net uart_in IOSTANDARD = LVCMOS33;
+Net uart_in TIG;
+Net uart_in PULLUP;
+
+Net uart_out LOC=AG20;
+#Net uart_out IOSTANDARD = LVCMOS33;
+Net uart_out TIG;
+Net uart_out PULLUP;
+
+
+
+
+
== Test ================================================================
#expect 25