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https://opencores.org/ocsvn/ao486/ao486/trunk
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[/] [ao486/] [trunk/] [doc/] [ethernet-io-dump.txt] - Rev 6
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To add an Ethernet real-time dump of io accesses make the following changes to the source code:
soc.v ports:
[
//debug - ethernet
output ENET0_GTX_CLK,
output ENET0_RST_N,
input ENET0_RX_CLK,
input [3:0] ENET0_RX_DATA,
input ENET0_RX_DV,
output [3:0] ENET0_TX_DATA,
output ENET0_TX_EN
]
soc.v u0 instantiation :
[
.ao486_conduit_dbg_tb_finish_instr (dbg_tb_finish_instr),
.ao486_conduit_dbg_dbg_io_address (dbg_io_address),
.ao486_conduit_dbg_dbg_io_byteenable (dbg_io_byteenable),
.ao486_conduit_dbg_dbg_io_write (dbg_io_write),
.ao486_conduit_dbg_dbg_io_read (dbg_io_read),
.ao486_conduit_dbg_dbg_io_data (dbg_io_data),
.ao486_conduit_dbg_dbg_int_vector (dbg_int_vector),
.ao486_conduit_dbg_dbg_int (dbg_int),
.ao486_conduit_dbg_dbg_exc_vector (dbg_exc_vector),
.ao486_conduit_dbg_dbg_exc (dbg_exc),
.ao486_conduit_dbg_dbg_mem_address (dbg_mem_address),
.ao486_conduit_dbg_dbg_mem_byteenable(dbg_mem_byteenable),
.ao486_conduit_dbg_dbg_mem_write (dbg_mem_write),
.ao486_conduit_dbg_dbg_mem_read (dbg_mem_read),
.ao486_conduit_dbg_dbg_mem_data (dbg_mem_data)
]
ao486.v ports:
[
//-------------------------------------------------------------------------- debug
input [17:0] SW,
output tb_finish_instr,
output [15:0] dbg_io_address,
output [3:0] dbg_io_byteenable,
output dbg_io_write,
output dbg_io_read,
output [31:0] dbg_io_data,
output [7:0] dbg_int_vector,
output dbg_int,
output [7:0] dbg_exc_vector,
output dbg_exc,
output [31:0] dbg_mem_address,
output [3:0] dbg_mem_byteenable,
output dbg_mem_write,
output dbg_mem_read,
output [31:0] dbg_mem_data
]
pipeline.v ports:
[
//debug
input [17:0] SW,
output tb_finish_instr
]
pipeline.v:
[
//---------------- debug
wire dbg_hold = dec_cmd != 7'd0 && dec_cmd > SW[6:0];
reg dbg_holding;
always @(posedge clk or negedge rst_n) begin
if(rst_n == 1'b0) dbg_holding <= 1'b0;
else if(dbg_eip_cnt == 32'hFFFFFFFF && SW[17]) dbg_holding <= 1'b1; //dummy
else if(dbg_hold) dbg_holding <= 1'b1;
else if(dbg_holding && rd_cmd == 7'd0 && ~(exe_mutex[10]) && ~(wr_mutex[10])) dbg_holding <= 1'b0;
end
reg [31:0] dbg_eip_cnt;
always @(posedge clk or negedge rst_n) begin
if(rst_n == 1'b0) dbg_eip_cnt <= 32'd0;
else if(dbg_eip_cnt == 32'd0 && eip[31]) dbg_eip_cnt <= 32'd1;
else if(dbg_eip_cnt != 32'd0) dbg_eip_cnt <= dbg_eip_cnt + 32'd1;
end
//---------------- debug
]
pipeline.v decode instantiation:
[
//TODO: delete: micro_busy || rd_cmd != 7'd0 || exe_mutex[10] || wr_mutex[10]
.micro_busy (micro_busy || ((dbg_hold || dbg_holding) && (rd_cmd != 7'd0 || exe_mutex[10] || wr_mutex[10]))), //input
]
ao486.v:
[
//--------------------------------------------------------------------------
assign dbg_io_address = (avalon_io_readdatavalid)? dbg_io_address_reg : avalon_io_address;
assign dbg_io_byteenable = (avalon_io_readdatavalid)? dbg_io_byteenable_reg : avalon_io_byteenable;
assign dbg_io_write = avalon_io_write && avalon_io_waitrequest == 1'b0;
assign dbg_io_read = avalon_io_readdatavalid;
assign dbg_io_data = (avalon_io_readdatavalid)? avalon_io_readdata : avalon_io_writedata;
reg [15:0] dbg_io_address_reg;
always @(posedge clk or negedge rst_n) begin
if(rst_n == 1'b0) dbg_io_address_reg <= 16'd0;
else if(avalon_io_read) dbg_io_address_reg <= avalon_io_address;
end
reg [3:0] dbg_io_byteenable_reg;
always @(posedge clk or negedge rst_n) begin
if(rst_n == 1'b0) dbg_io_byteenable_reg <= 4'd0;
else if(avalon_io_read) dbg_io_byteenable_reg <= avalon_io_byteenable;
end
assign dbg_int_vector = interrupt_vector;
assign dbg_int = interrupt_done;
assign dbg_exc_vector = exc_vector;
assign dbg_exc = exc_init && (wr_interrupt_possible == 1'b0 || interrupt_do == 1'b0) && interrupt_done == 1'b0;
//-----
reg [31:0] dbg_mem_address_reg;
always @(posedge clk or negedge rst_n) begin
if(rst_n == 1'b0) dbg_mem_address_reg <= 32'd0;
else if(avm_read && dbg_mem_vga && avm_waitrequest == 1'b0) dbg_mem_address_reg <= avm_address;
else if(dbg_mem_is_read_reg && avm_readdatavalid) dbg_mem_address_reg <= dbg_mem_address_reg + 32'd4;
else if(avm_write && dbg_mem_is_write_reg == 1'b0 && avm_waitrequest == 1'b0) dbg_mem_address_reg <= avm_address + 32'd4;
else if(avm_write && dbg_mem_is_write_reg && avm_waitrequest == 1'b0) dbg_mem_address_reg <= dbg_mem_address_reg + 32'd4;
end
reg [3:0] dbg_mem_byteenable_reg;
always @(posedge clk or negedge rst_n) begin
if(rst_n == 1'b0) dbg_mem_byteenable_reg <= 4'd0;
else if(avm_read && dbg_mem_vga && avm_waitrequest == 1'b0) dbg_mem_byteenable_reg <= avm_byteenable;
end
reg [2:0] dbg_mem_burstcount_reg;
always @(posedge clk or negedge rst_n) begin
if(rst_n == 1'b0) dbg_mem_burstcount_reg <= 3'd0;
else if(avm_read && dbg_mem_vga && avm_waitrequest == 1'b0 && avm_burstcount > 3'd1) dbg_mem_burstcount_reg <= avm_burstcount - 3'd1;
else if(dbg_mem_is_read_reg && avm_readdatavalid && dbg_mem_burstcount_reg > 3'd0) dbg_mem_burstcount_reg <= dbg_mem_burstcount_reg - 3'd1;
else if(avm_write && dbg_mem_is_write_reg == 1'b0 && avm_waitrequest == 1'b0 && avm_burstcount > 3'd1) dbg_mem_burstcount_reg <= avm_burstcount - 3'd1;
else if(avm_write && dbg_mem_is_write_reg && avm_waitrequest == 1'b0 && dbg_mem_burstcount_reg > 3'd0) dbg_mem_burstcount_reg <= dbg_mem_burstcount_reg - 3'd1;
end
wire dbg_mem_vga = avm_address >= 32'h000A0000 && avm_address < 32'h000C0000;
reg dbg_mem_is_read_reg;
always @(posedge clk or negedge rst_n) begin
if(rst_n == 1'b0) dbg_mem_is_read_reg <= 1'b0;
else if(avm_read && dbg_mem_vga && avm_waitrequest == 1'b0) dbg_mem_is_read_reg <= 1'b1;
else if(dbg_mem_is_read_reg && avm_readdatavalid && dbg_mem_burstcount_reg <= 3'd1) dbg_mem_is_read_reg <= 1'b0;
end
reg dbg_mem_is_write_reg;
always @(posedge clk or negedge rst_n) begin
if(rst_n == 1'b0) dbg_mem_is_write_reg <= 1'b0;
else if(avm_write && dbg_mem_is_write_reg == 1'b0 && avm_waitrequest == 1'b0 && avm_burstcount > 3'd1) dbg_mem_is_write_reg <= 1'b1;
else if(avm_write && dbg_mem_is_write_reg && avm_waitrequest == 1'b0 && dbg_mem_burstcount_reg <= 3'd1) dbg_mem_is_write_reg <= 1'b0;
end
assign dbg_mem_address = (dbg_mem_is_read_reg || dbg_mem_is_write_reg)? dbg_mem_address_reg : avm_address;
assign dbg_mem_byteenable = (dbg_mem_is_read_reg)? dbg_mem_byteenable_reg : avm_byteenable;
assign dbg_mem_read = dbg_mem_is_read_reg && avm_readdatavalid;
assign dbg_mem_write = avm_write && avm_waitrequest == 1'b0;
assign dbg_mem_data = (dbg_mem_is_read_reg)? avm_readdata : avm_writedata;
]
ao486.v pipeline instantiation:
[
//debug
.SW (SW), //input [17:0]
.tb_finish_instr (tb_finish_instr) //output
]
soc.v:
[
//------------------------------------------------------------------------------
wire dbg_tb_finish_instr;
wire [15:0] dbg_io_address;
wire [3:0] dbg_io_byteenable;
wire dbg_io_write;
wire dbg_io_read;
wire [31:0] dbg_io_data;
wire [7:0] dbg_int_vector;
wire dbg_int;
wire [7:0] dbg_exc_vector;
wire dbg_exc;
wire [31:0] dbg_mem_address;
wire [3:0] dbg_mem_byteenable;
wire dbg_mem_write;
wire dbg_mem_read;
wire [31:0] dbg_mem_data;
//------------------------------------------------------------------------------ ethernet debug
wire enet_rst_n;
wire [5:0] enet_clk;
altpll pll_eth_inst (
.inclk ( {1'b0, CLOCK_50} ),
.clk (enet_clk),
.locked (enet_rst_n)
);
defparam
pll_eth_inst.clk0_divide_by = 2,
pll_eth_inst.clk0_duty_cycle = 50,
pll_eth_inst.clk0_multiply_by = 5,
pll_eth_inst.clk0_phase_shift = "0",
pll_eth_inst.clk1_divide_by = 2,
pll_eth_inst.clk1_duty_cycle = 50,
pll_eth_inst.clk1_multiply_by = 5,
pll_eth_inst.clk1_phase_shift = "2000",
pll_eth_inst.compensate_clock = "CLK0",
pll_eth_inst.inclk0_input_frequency = 20000,
pll_eth_inst.operation_mode = "NO_COMPENSATION";
wire enet_clk_data = enet_clk[0];
wire enet_clk_clock = enet_clk[1];
assign ENET0_RST_N = enet_rst_cnt == 20'hFFFFF;
reg [19:0] enet_rst_cnt;
always @(posedge enet_clk_data or negedge enet_rst_n) begin
if(enet_rst_n == 1'b0) enet_rst_cnt <= 20'd0;
else if(enet_rst_cnt < 20'hFFFFF) enet_rst_cnt <= enet_rst_cnt + 20'd1;
end
//------------------------------------------------------------------------------
reg [39:0] dbg_tb_finish_instr_reg;
always @(posedge clk_sys or negedge rst_n) begin
if(rst_n == 1'b0) dbg_tb_finish_instr_reg <= 40'd0;
else if(dbg_tb_finish_instr) dbg_tb_finish_instr_reg <= dbg_tb_finish_instr_reg + 40'd1;
end
//------------------------------------------------------------------------------
reg [7:0] dbg_int_vector_reg;
reg dbg_int_reg;
always @(posedge clk_sys or negedge rst_n) begin
if(rst_n == 1'b0) dbg_int_vector_reg <= 8'd0;
else if(dbg_int_reg == 1'b0) dbg_int_vector_reg <= dbg_int_vector;
end
wire dbg_int_reg_lower = dbg_int_reg && dbg_mem_read_reg == 1'b0 && dbg_mem_write_reg == 1'b0 && dbg_io_read_reg == 1'b0 && dbg_io_write_reg == 1'b0;
always @(posedge clk_sys or negedge rst_n) begin
if(rst_n == 1'b0) dbg_int_reg <= 1'd0;
else if(dbg_int_reg == 1'b0) dbg_int_reg <= dbg_int;
else if(dbg_int_reg_lower) dbg_int_reg <= 1'b0;
end
reg [7:0] dbg_exc_vector_reg;
reg dbg_exc_reg;
always @(posedge clk_sys or negedge rst_n) begin
if(rst_n == 1'b0) dbg_exc_vector_reg <= 8'd0;
else if(dbg_exc_reg == 1'b0) dbg_exc_vector_reg <= dbg_exc_vector;
end
wire dbg_exc_reg_lower = dbg_exc_reg && dbg_mem_read_reg == 1'b0 && dbg_mem_write_reg == 1'b0 && dbg_io_read_reg == 1'b0 && dbg_io_write_reg == 1'b0 && dbg_int_reg == 1'b0;
always @(posedge clk_sys or negedge rst_n) begin
if(rst_n == 1'b0) dbg_exc_reg <= 1'd0;
else if(dbg_exc_reg == 1'b0) dbg_exc_reg <= dbg_exc;
else if(dbg_exc_reg_lower) dbg_exc_reg <= 1'b0;
end
reg [15:0] dbg_io_address_reg;
reg [3:0] dbg_io_byteenable_reg;
reg dbg_io_write_reg;
reg dbg_io_read_reg;
reg [31:0] dbg_io_data_reg;
always @(posedge clk_sys or negedge rst_n) begin if(rst_n == 1'b0) dbg_io_address_reg <= 16'd0; else dbg_io_address_reg <= dbg_io_address; end
always @(posedge clk_sys or negedge rst_n) begin if(rst_n == 1'b0) dbg_io_byteenable_reg <= 4'd0; else dbg_io_byteenable_reg <= dbg_io_byteenable; end
always @(posedge clk_sys or negedge rst_n) begin if(rst_n == 1'b0) dbg_io_write_reg <= 1'd0; else dbg_io_write_reg <= dbg_io_write; end
always @(posedge clk_sys or negedge rst_n) begin if(rst_n == 1'b0) dbg_io_read_reg <= 1'd0; else dbg_io_read_reg <= dbg_io_read; end
always @(posedge clk_sys or negedge rst_n) begin if(rst_n == 1'b0) dbg_io_data_reg <= 32'd0; else dbg_io_data_reg <= dbg_io_data; end
reg [31:0] dbg_mem_address_reg;
reg [3:0] dbg_mem_byteenable_reg;
reg dbg_mem_write_reg;
reg dbg_mem_read_reg;
reg [31:0] dbg_mem_data_reg;
always @(posedge clk_sys or negedge rst_n) begin if(rst_n == 1'b0) dbg_mem_address_reg <= 32'd0; else dbg_mem_address_reg <= dbg_mem_address; end
always @(posedge clk_sys or negedge rst_n) begin if(rst_n == 1'b0) dbg_mem_byteenable_reg <= 4'd0; else dbg_mem_byteenable_reg <= dbg_mem_byteenable; end
always @(posedge clk_sys or negedge rst_n) begin if(rst_n == 1'b0) dbg_mem_write_reg <= 1'd0; else dbg_mem_write_reg <= dbg_mem_write; end
always @(posedge clk_sys or negedge rst_n) begin if(rst_n == 1'b0) dbg_mem_read_reg <= 1'd0; else dbg_mem_read_reg <= dbg_mem_read; end
always @(posedge clk_sys or negedge rst_n) begin if(rst_n == 1'b0) dbg_mem_data_reg <= 32'd0; else dbg_mem_data_reg <= dbg_mem_data; end
//------------------------------------------------------------------------------
wire [71:0] dbg_step1_q;
wire dbg_step1_empty;
wire [9:0] dbg_step1_usedw;
wire [71:0] dbg_a_next =
(dbg_mem_read_reg || dbg_mem_write_reg)? { 2'd1, dbg_mem_address_reg, dbg_mem_data_reg, dbg_mem_byteenable_reg, dbg_mem_write_reg, dbg_mem_read_reg } :
(dbg_io_read_reg || dbg_io_write_reg)? { 2'd2, 16'd0, dbg_io_address_reg, dbg_io_data_reg, dbg_io_byteenable_reg, dbg_io_write_reg, dbg_io_read_reg } :
(dbg_int_reg_lower)? { 2'd3, 22'd0, dbg_tb_finish_instr_reg, dbg_int_vector_reg } :
{ 2'd3, 1'd1, 21'd0, dbg_tb_finish_instr_reg, dbg_exc_vector_reg };
scfifo scfifo_a_inst(
.clock (clk_sys),
.wrreq (dbg_mem_read_reg || dbg_mem_write_reg || dbg_io_read_reg || dbg_io_write_reg || dbg_int_reg_lower || dbg_exc_reg_lower),
.data (dbg_a_next),
.rdreq (dbg_a_state_enable && dbg_a_state == 2'd2),
.q (dbg_step1_q),
.empty (dbg_step1_empty),
.usedw (dbg_step1_usedw)
);
defparam
scfifo_a_inst.lpm_width = 72,
scfifo_a_inst.lpm_widthu = 10,
scfifo_a_inst.lpm_numwords = 1024,
scfifo_a_inst.lpm_showahead = "ON";
wire dbg_a_state_start = dbg_step1_step >= 9'd12 && dbg_step1_step <= 9'd376 && dbg_a_state == 2'd0 && dbg_step1_empty == 1'b0;
wire dbg_a_state_enable= dbg_step1_step >= 9'd12 && dbg_step1_step <= 9'd376 && (dbg_a_state == 2'd1 || dbg_a_state == 2'd2);
reg [1:0] dbg_a_state;
always @(posedge clk_sys or negedge rst_n) begin
if(rst_n == 1'b0) dbg_a_state <= 2'd0;
else if(dbg_a_state_start) dbg_a_state <= 2'd1;
else if(dbg_a_state_enable && dbg_a_state == 2'd1) dbg_a_state <= 2'd2;
else if(dbg_a_state_enable && dbg_a_state == 2'd2) dbg_a_state <= 2'd0;
end
//------------------------------------------------------------------------------
// d4 3d 7e 00 e9 c4 - 00 11 22 33 44 55 - 08 00 -
// 45 00 05 d2 00 00 40 00 40 11 - 1e 51 - 0a 01 01 65 0a 01 01 64 //1490 = 365*4+ 20 + 8 + 2
// cc dd cc de 05 be 00 00
wire [31:0] dbg_step1_part =
(dbg_a_state == 2'd0)? dbg_step1_q[71:40] :
(dbg_a_state == 2'd1)? dbg_step1_q[39:8] :
{ dbg_step1_q[7:0], 24'd0 };
reg [19:0] dbg_step1_counter;
always @(posedge clk_sys or negedge rst_n) begin
if(rst_n == 1'b0) dbg_step1_counter <= 20'd0;
else if(dbg_step1_step_last) dbg_step1_counter <= 20'd0;
else if(dbg_step1_empty) dbg_step1_counter <= 20'd0;
else if(dbg_step1_step == 9'd0) dbg_step1_counter <= dbg_step1_counter + 20'd1;
end
wire dbg_step1_start =
dbg_step1_empty == 1'b0 && (dbg_step1_usedw == 10'd0 || dbg_step1_usedw > 10'd121 || dbg_step1_counter == 20'hFFFFF);
reg [8:0] dbg_step1_step;
always @(posedge clk_sys or negedge rst_n) begin
if(rst_n == 1'b0) dbg_step1_step <= 9'd0;
else if(dbg_step1_step == 9'd0 && dbg_step1_start) dbg_step1_step <= 9'd1;
else if(dbg_step1_step_last) dbg_step1_step <= 9'd0;
else if(dbg_step1_step > 9'd0) dbg_step1_step <= dbg_step1_step + 9'd1;
end
wire dbg_step1_step_last = dbg_step1_step == 9'd376;
reg [15:0] dbg_io_counter;
always @(posedge clk_sys or negedge rst_n) begin
if(rst_n == 1'b0) dbg_io_counter <= 16'd0;
else if(dbg_step1_step == 9'd11) dbg_io_counter <= dbg_io_counter + 16'd1;
end
wire [31:0] dbg_step1_next =
(dbg_step1_step == 9'd1)? 32'hD43D7E00 :
(dbg_step1_step == 9'd2)? 32'hE9C40011 :
(dbg_step1_step == 9'd3)? 32'h22334455 :
(dbg_step1_step == 9'd4)? 32'h08004500 :
(dbg_step1_step == 9'd5)? 32'h05D20000 :
(dbg_step1_step == 9'd6)? 32'h40004011 :
(dbg_step1_step == 9'd7)? 32'h1E510A01 :
(dbg_step1_step == 9'd8)? 32'h01650A01 :
(dbg_step1_step == 9'd9)? 32'h0164CCDD :
(dbg_step1_step == 9'd10)? 32'hCCDE05BE :
(dbg_step1_step == 9'd11)? { 16'h0000, dbg_io_counter } :
(dbg_step1_empty)? 32'h00000000 :
dbg_step1_part;
//------------------------------------------------------------------------------
wire [34:0] out_dc_q;
wire out_dc_empty;
wire [9:0] out_dc_rdusedw;
dcfifo dcfifo_inst(
.wrclk (clk_sys),
.wrreq (dbg_step1_step != 9'd0),
.data ({ dbg_step1_step_last, 2'b0, dbg_step1_next }),
.rdclk (enet_clk_data),
.rdreq (out_dc_rdreq),
.q (out_dc_q),
.rdempty (out_dc_empty),
.rdusedw (out_dc_rdusedw)
);
defparam
dcfifo_inst.lpm_width = 35,
dcfifo_inst.lpm_widthu = 10,
dcfifo_inst.lpm_numwords = 1024;
wire out_dc_rdreq;
mac_output mac_output_inst(
.clk_data (enet_clk_data),
.clk_clock (enet_clk_clock),
.rst_n (enet_rst_n),
.fifo_empty (out_dc_empty || out_dc_rdusedw < 10'd375),
.fifo_rdreq (out_dc_rdreq),
// 34: end, 33,32: not valid
.fifo_q (out_dc_q),
.phy_txc (ENET0_GTX_CLK),
.phy_ddio_td (ENET0_TX_DATA),
.phy_ddio_tx_ctl(ENET0_TX_EN),
.slow (1'b0)
);
//------------------------------------------------------------------------------
endmodule
//------------------------------------------------------------------------------ ethernet output mac
module mac_output(
input clk_data,
input clk_clock,
input rst_n,
input fifo_empty,
output fifo_rdreq,
// 34: end, 33,32: not valid
input [34:0] fifo_q,
output phy_txc,
output [3:0] phy_ddio_td,
output phy_ddio_tx_ctl,
input slow
);
// *************************************************** TXC clock
altddio_out ddio_clk_inst(
.outclock (clk_clock),
.datain_h (1'b1),
.datain_l (1'b0),
.dataout (phy_txc)
);
defparam ddio_clk_inst.width = 1;
// *************************************************** DDIO
wire [7:0] phy_data_final;
reg phy_valid;
altddio_out ddio_td_inst(
.outclock (clk_data),
.datain_h (phy_data_final[3:0]),
.datain_l (phy_data_final[7:4]),
.dataout (phy_ddio_td)
);
defparam ddio_td_inst.width = 4;
altddio_out ddio_tx_ctl_inst(
.outclock (clk_data),
.datain_h (phy_valid),
.datain_l (phy_valid),
.dataout (phy_ddio_tx_ctl)
);
defparam ddio_tx_ctl_inst.width = 1;
wire idle;
// *************************************************** speed
reg slow_reg_1;
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) slow_reg_1 <= 1'b0;
else slow_reg_1 <= slow;
end
reg slow_reg_2;
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) slow_reg_2 <= 1'b0;
else slow_reg_2 <= slow_reg_1;
end
reg slow_reg;
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) slow_reg <= 1'b0;
else if(slow_reg_1 == slow_reg_2 && idle) slow_reg <= slow_reg_2;
end
reg toggle;
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) toggle <= 1'b0;
else if(slow_reg) toggle <= ~toggle;
else toggle <= 1'b0;
end
wire enabled = slow_reg == 1'b0 || toggle;
// *************************************************** data path
wire [31:0] crc_output;
wire crc_load;
wire start_preamble;
reg [2:0] preamble_cnt;
wire phy_valid_value;
reg fifo_rdreq_reg;
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) fifo_rdreq_reg <= 1'b0;
else fifo_rdreq_reg <= fifo_rdreq;
end
reg [7:0] phy_data_1;
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) phy_data_1 <= 8'd0;
else if(enabled) begin
if(fifo_rdreq_reg) phy_data_1 <= fifo_q[7:0];
end
end
reg [7:0] phy_data_2;
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) phy_data_2 <= 8'd0;
else if(enabled) begin
if(crc_load) phy_data_2 <= crc_output[7:0];
else if(fifo_rdreq_reg) phy_data_2 <= fifo_q[15:8];
else phy_data_2 <= phy_data_1;
end
end
reg [7:0] phy_data_3;
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) phy_data_3 <= 8'd0;
else if(enabled) begin
if(crc_load) phy_data_3 <= crc_output[15:8];
else if(fifo_rdreq_reg) phy_data_3 <= fifo_q[23:16];
else phy_data_3 <= phy_data_2;
end
end
reg [7:0] phy_data_4;
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) phy_data_4 <= 8'd0;
else if(enabled) begin
if(crc_load) phy_data_4 <= crc_output[23:16];
else if(fifo_rdreq_reg) phy_data_4 <= fifo_q[31:24];
else phy_data_4 <= phy_data_3;
end
end
reg [7:0] phy_data_5;
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) phy_data_5 <= 8'd0;
else if(enabled) begin
if(crc_load) phy_data_5 <= crc_output[31:24];
else if(preamble_cnt == 3'd7) phy_data_5 <= 8'hD5;
else if(start_preamble || preamble_cnt != 3'd0) phy_data_5 <= 8'h55;
else if(phy_valid_value == 1'b0) phy_data_5 <= 8'h00;
else phy_data_5 <= phy_data_4;
end
end
//-
assign phy_data_final = (slow == 1'b0)? phy_data_5 : (enabled)? { phy_data_5[7:4], phy_data_5[7:4] } : { phy_data_5[3:0], phy_data_5[3:0] };
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) phy_valid <= 1'b0;
else if(enabled) begin
phy_valid <= phy_valid_value;
end
end
// *************************************************** counters
reg [2:0] left_cnt;
reg [4:0] gap_cnt;
reg [31:0] crc;
assign idle = preamble_cnt == 4'd0 && left_cnt == 3'd0 && gap_cnt == 5'd0;
assign start_preamble = idle && fifo_empty == 1'b0;
assign phy_valid_value = start_preamble || preamble_cnt != 4'd0 || left_cnt != 3'd0 || gap_cnt >= 5'd13;
wire crc_count = left_cnt != 3'd0 || gap_cnt >= 5'd17;
assign crc_load = gap_cnt == 5'd16;
assign fifo_rdreq = (slow_reg == 1'b0 && (preamble_cnt == 4'd6 || left_cnt == 3'd2)) || (slow_reg && enabled == 1'b0 && (preamble_cnt == 4'd7 || left_cnt == 3'd1));
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) preamble_cnt <= 3'd0;
else if(enabled) begin
if(start_preamble || preamble_cnt != 3'd0) preamble_cnt <= preamble_cnt + 3'd1;
end
end
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) left_cnt <= 3'd0;
else if(enabled) begin
if(fifo_rdreq_reg && fifo_q[34] == 1'b0) left_cnt <= 3'd4;
else if(fifo_rdreq_reg) left_cnt <= 3'd0;
else if(left_cnt > 3'd0) left_cnt <= left_cnt - 3'd1;
end
end
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) gap_cnt <= 5'd0;
else if(enabled) begin
if(fifo_rdreq_reg && fifo_q[34] == 1'b1) gap_cnt <= 5'd20 - { 3'b0, fifo_q[33:32] };
else if(gap_cnt > 5'd0) gap_cnt <= gap_cnt - 5'd1;
end
end
// *************************************************** crc
wire [31:0] crc_rev = {
crc[24],crc[25],crc[26],crc[27],crc[28],crc[29],crc[30],crc[31],
crc[16],crc[17],crc[18],crc[19],crc[20],crc[21],crc[22],crc[23],
crc[8], crc[9], crc[10],crc[11],crc[12],crc[13],crc[14],crc[15],
crc[0], crc[1], crc[2], crc[3], crc[4], crc[5], crc[6], crc[7]
};
assign crc_output = ~crc_rev;
wire [31:0] crc_next = {
phy_data_4[2] ^ crc[23] ^ crc[29],
phy_data_4[0] ^ phy_data_4[3] ^ crc[22] ^ crc[28] ^ crc[31],
phy_data_4[0] ^ phy_data_4[1] ^ phy_data_4[4] ^ crc[21] ^ crc[27] ^ crc[30] ^ crc[31],
phy_data_4[1] ^ phy_data_4[2] ^ phy_data_4[5] ^ crc[20] ^ crc[26] ^ crc[29] ^ crc[30],
phy_data_4[0] ^ phy_data_4[2] ^ phy_data_4[3] ^ phy_data_4[6] ^ crc[19] ^ crc[25] ^ crc[28] ^ crc[29] ^ crc[31],
phy_data_4[1] ^ phy_data_4[3] ^ phy_data_4[4] ^ phy_data_4[7] ^ crc[18] ^ crc[24] ^ crc[27] ^ crc[28] ^ crc[30],
phy_data_4[4] ^ phy_data_4[5] ^ crc[17] ^ crc[26] ^ crc[27],
phy_data_4[0] ^ phy_data_4[5] ^ phy_data_4[6] ^ crc[16] ^ crc[25] ^ crc[26] ^ crc[31],
phy_data_4[1] ^ phy_data_4[6] ^ phy_data_4[7] ^ crc[15] ^ crc[24] ^ crc[25] ^ crc[30],
phy_data_4[7] ^ crc[14] ^ crc[24],
phy_data_4[2] ^ crc[13] ^ crc[29],
phy_data_4[3] ^ crc[12] ^ crc[28],
phy_data_4[0] ^ phy_data_4[4] ^ crc[11] ^ crc[27] ^ crc[31],
phy_data_4[0] ^ phy_data_4[1] ^ phy_data_4[5] ^ crc[10] ^ crc[26] ^ crc[30] ^ crc[31],
phy_data_4[1] ^ phy_data_4[2] ^ phy_data_4[6] ^ crc[9] ^ crc[25] ^ crc[29] ^ crc[30],
phy_data_4[2] ^ phy_data_4[3] ^ phy_data_4[7] ^ crc[8] ^ crc[24] ^ crc[28] ^ crc[29],
phy_data_4[0] ^ phy_data_4[2] ^ phy_data_4[3] ^ phy_data_4[4] ^ crc[7] ^ crc[27] ^ crc[28] ^ crc[29] ^ crc[31],
phy_data_4[0] ^ phy_data_4[1] ^ phy_data_4[3] ^ phy_data_4[4] ^ phy_data_4[5] ^ crc[6] ^ crc[26] ^ crc[27] ^ crc[28] ^ crc[30] ^ crc[31],
phy_data_4[0] ^ phy_data_4[1] ^ phy_data_4[2] ^ phy_data_4[4] ^ phy_data_4[5] ^ phy_data_4[6] ^ crc[5] ^ crc[25] ^ crc[26] ^ crc[27] ^ crc[29] ^ crc[30] ^ crc[31],
phy_data_4[1] ^ phy_data_4[2] ^ phy_data_4[3] ^ phy_data_4[5] ^ phy_data_4[6] ^ phy_data_4[7] ^ crc[4] ^ crc[24] ^ crc[25] ^ crc[26] ^ crc[28] ^ crc[29] ^ crc[30],
phy_data_4[3] ^ phy_data_4[4] ^ phy_data_4[6] ^ phy_data_4[7] ^ crc[3] ^ crc[24] ^ crc[25] ^ crc[27] ^ crc[28],
phy_data_4[2] ^ phy_data_4[4] ^ phy_data_4[5] ^ phy_data_4[7] ^ crc[2] ^ crc[24] ^ crc[26] ^ crc[27] ^ crc[29],
phy_data_4[2] ^ phy_data_4[3] ^ phy_data_4[5] ^ phy_data_4[6] ^ crc[1] ^ crc[25] ^ crc[26] ^ crc[28] ^ crc[29],
phy_data_4[3] ^ phy_data_4[4] ^ phy_data_4[6] ^ phy_data_4[7] ^ crc[0] ^ crc[24] ^ crc[25] ^ crc[27] ^ crc[28],
phy_data_4[0] ^ phy_data_4[2] ^ phy_data_4[4] ^ phy_data_4[5] ^ phy_data_4[7] ^ crc[24] ^ crc[26] ^ crc[27] ^ crc[29] ^ crc[31],
phy_data_4[0] ^ phy_data_4[1] ^ phy_data_4[2] ^ phy_data_4[3] ^ phy_data_4[5] ^ phy_data_4[6] ^ crc[25] ^ crc[26] ^ crc[28] ^ crc[29] ^ crc[30] ^ crc[31],
phy_data_4[0] ^ phy_data_4[1] ^ phy_data_4[2] ^ phy_data_4[3] ^ phy_data_4[4] ^ phy_data_4[6] ^ phy_data_4[7] ^ crc[24] ^ crc[25] ^ crc[27] ^ crc[28] ^ crc[29] ^ crc[30] ^ crc[31],
phy_data_4[1] ^ phy_data_4[3] ^ phy_data_4[4] ^ phy_data_4[5] ^ phy_data_4[7] ^ crc[24] ^ crc[26] ^ crc[27] ^ crc[28] ^ crc[30],
phy_data_4[0] ^ phy_data_4[4] ^ phy_data_4[5] ^ phy_data_4[6] ^ crc[25] ^ crc[26] ^ crc[27] ^ crc[31],
phy_data_4[0] ^ phy_data_4[1] ^ phy_data_4[5] ^ phy_data_4[6] ^ phy_data_4[7] ^ crc[24] ^ crc[25] ^ crc[26] ^ crc[30] ^ crc[31],
phy_data_4[0] ^ phy_data_4[1] ^ phy_data_4[6] ^ phy_data_4[7] ^ crc[24] ^ crc[25] ^ crc[30] ^ crc[31],
phy_data_4[1] ^ phy_data_4[7] ^ crc[24] ^ crc[30]
};
always @(posedge clk_data or negedge rst_n) begin
if(rst_n == 1'b0) crc <= 32'hFFFFFFFF;
else if(enabled) begin
if(crc_count) crc <= crc_next;
else if(crc_load) crc <= 32'hFFFFFFFF;
end
end
endmodule
]
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
For disabling the pipeline (serial insruction execution):
pipeline.v write instantiation:
[
.tb_finish_instr (tb_finish_instr)
]
write.v ports:
[
//debug
output tb_finish_instr
]
write.v:
[
assign tb_finish_instr = wr_finished || (wr_ready && wr_hlt_in_progress);
]
soc.v ports:
[
//debug
input [17:0] SW,
]
soc.v u0 instantiation:
[
//debug
.ao486_debug_sw_export (SW),
]
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
pit.v:
[
/*
reg counter_1_out_last;
always @(posedge clk or negedge rst_n) begin
if(rst_n == 1'b0) counter_1_out_last <= 1'b0;
else counter_1_out_last <= counter_1_out;
end
reg counter_1_toggle;
always @(posedge clk or negedge rst_n) begin
if(rst_n == 1'b0) counter_1_toggle <= 1'b0;
else if(counter_1_out_last == 1'b0 && counter_1_out == 1'b1) counter_1_toggle <= ~(counter_1_toggle);
end
*/
]
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
TODO list:
floppy.v:
[
//TODO: in execute_ndma -- send irq after every byte
]
ao486:
[
//TODO: if repeat and interrupt --> eip = eip_prev;
//TODO: IN,INS, OUT,OUTS --> wait for prev. instr. -- exception possible
//TODO: task switch --> disable inhibits and debug traps
//TODO: interrupt --> disable inhibits and debug traps
//TODO: task switch --> IRET -- test with PG active
//TODO: read io only once in rd (if pipeline blocked, many reads can start)
//TODO: tlbflushall in memory
//TODO: wait in mult/div with busy=0 (wr can be busy)
//TODO: tflag_to_reg -- check if wr stage does not block
//TODO: JCXZ,LOOP .... reset pr,micro,dec; exe,wr can reset again
//TODO: tlb 2.6.2: if(pg disabled) access bits not set
//TODO: 2.6.2: EXT, change in table (?)
//TODO: 2.6.2: single-step after task switch
//TODO: interrupt_do -- in write checked and in exception -- must keep stable unit one cycle after interrupt_done -- changed:
// cycle 1: interrupt_do active
// cycle 2: interrupt_do don't care
// cycle 3: interrupt_done active for one cycle; interrupt_vector is sampled
//TODO: error code push test in exception
//TODO: soc: dma transfer and caching
//TODO: write to code already prefetched
//assign wr_req_reset_write_over_prefetch = wr_finished && write_for_wr_ready && write_over_prefetch && ~(wr_eip_has_next_eip);
//assign wr_eip_from_wr_eip = wr_exe_eip_from_wr_eip || wr_req_reset_write_over_prefetch;
/*
-T in TSS
-TF (inhibit; with RF in string instructions)
-instruction breakpoint
-data breakpoint
-debug registers (MOV; updates; exceptions)
AC flag
INVD,WBINVD,INVLPG
MOV Dx
-debug
-paging
*/
// From bochs arith32.cc version 2.4
// Some info on the opcodes at {0F,A6} and {0F,A7}
// On 386 steps A0-B0:
// {OF,A6} = XBTS
// {OF,A7} = IBTS
// On 486 steps A0-B0:
// {OF,A6} = CMPXCHG 8
// {OF,A7} = CMPXCHG 16|32
//
// On 486 >= B steps, and further processors, the
// CMPXCHG instructions were moved to opcodes:
// {OF,B0} = CMPXCHG 8
// {OF,B1} = CMPXCHG 16|32
]
defines.v mutex:
[
//`include "startup_from_sim.v"
//TODO: check that exe_waiting is active, if e*x is used in exe and busy_full[] is used
]
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