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ym_lib.v
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module ym_sr_bit #(parameter SR_LENGTH = 1)
(
input MCLK,
input c1,
input c2,
input inp,
output val
);
reg [SR_LENGTH-1:0] v1 = 0;
reg [SR_LENGTH-1:0] v2 = 0;
wire [SR_LENGTH-1:0] v2_assign = c2 ? v1 : v2;
assign val = v2[SR_LENGTH-1];
always @(posedge MCLK)
begin
if (c1)
begin
if (SR_LENGTH == 1)
v1 <= inp;
else
v1 <= { v2[SR_LENGTH-2:0], inp };
end
v2 <= v2_assign;
end
endmodule
module ym_sr_bit_array #(parameter SR_LENGTH = 1, DATA_WIDTH = 1)
(
input MCLK,
input c1,
input c2,
input [DATA_WIDTH-1:0] inp,
output [DATA_WIDTH-1:0] val
);
wire out[0:DATA_WIDTH-1];
generate
genvar i;
for (i = 0; i < DATA_WIDTH; i = i + 1)
begin : l1
ym_sr_bit #(.SR_LENGTH(SR_LENGTH)) sr (
.MCLK(MCLK),
.c1(c1),
.c2(c2),
.inp(inp[i]),
.val(out[i])
);
assign val[i] = out[i];
end
endgenerate
endmodule
module ym_cnt_bit #(parameter DATA_WIDTH = 1)
(
input MCLK,
input c1,
input c2,
input c_in,
input rst,
output [DATA_WIDTH-1:0] val,
output c_out
);
wire [DATA_WIDTH-1:0] data_in;
wire [DATA_WIDTH-1:0] data_out;
wire [DATA_WIDTH:0] sum;
ym_sr_bit_array #(.DATA_WIDTH(DATA_WIDTH)) mem
(
.MCLK(MCLK),
.c1(c1),
.c2(c2),
.inp(data_in),
.val(data_out)
);
assign sum = { 1'h0, data_out } + {{DATA_WIDTH{1'h0}}, c_in};
assign val = data_out;
assign data_in = rst ? {DATA_WIDTH{1'h0}} : sum[DATA_WIDTH-1:0];
assign c_out = sum[DATA_WIDTH];
endmodule
module ym_dlatch #(parameter DATA_WIDTH = 1)
(
input MCLK,
input en,
input [DATA_WIDTH-1:0] inp,
output [DATA_WIDTH-1:0] val,
output [DATA_WIDTH-1:0] nval
);
reg [DATA_WIDTH-1:0] mem = {DATA_WIDTH{1'h0}};
wire [DATA_WIDTH-1:0] mem_assign = en ? inp : mem;
always @(posedge MCLK)
begin
mem <= mem_assign;
end
//assign val = mem_assign;
//assign nval = ~mem_assign;
assign val = mem;
assign nval = ~mem;
endmodule
module ym_edge_detect
(
input MCLK,
input c1,
input inp,
output val
);
wire prev_out;
ym_dlatch prev
(
.MCLK(MCLK),
.en(c1),
.inp(inp),
.val(prev_out),
.nval()
);
assign val = ~(prev_out | ~inp);
endmodule
module ym_slatch #(parameter DATA_WIDTH = 1)
(
input MCLK,
input en,
input [DATA_WIDTH-1:0] inp,
output [DATA_WIDTH-1:0] val,
output [DATA_WIDTH-1:0] nval
);
reg [DATA_WIDTH-1:0] mem = {DATA_WIDTH{1'h0}};
wire [DATA_WIDTH-1:0] mem_assign = en ? inp : mem;
always @(posedge MCLK)
begin
mem <= mem_assign;
end
assign val = mem;
assign nval = ~mem;
endmodule
module ym_rs_trig
(
input MCLK,
input set,
input rst,
output reg q = 1'h0,
output reg nq = 1'h1
);
always @(posedge MCLK)
begin
q <= rst ? 1'h0 : (set ? 1'h1 : q);
nq <= set ? 1'h0 : (rst ? 1'h1 : ~q);
end
endmodule
module ym_cnt_bit_load #(parameter DATA_WIDTH = 1)
(
input MCLK,
input c1,
input c2,
input c_in,
input rst,
input load,
input [DATA_WIDTH-1:0] load_val,
output [DATA_WIDTH-1:0] val,
output c_out
);
wire [DATA_WIDTH-1:0] data_in;
wire [DATA_WIDTH-1:0] data_out;
wire [DATA_WIDTH:0] sum;
ym_sr_bit_array #(.DATA_WIDTH(DATA_WIDTH)) mem
(
.MCLK(MCLK),
.c1(c1),
.c2(c2),
.inp(data_in),
.val(data_out)
);
wire [DATA_WIDTH-1:0] base_val = load ? load_val : data_out;
assign sum = {1'h0, base_val} + {{DATA_WIDTH{1'h0}},c_in};
assign data_in = rst ? {DATA_WIDTH{1'h0}} : sum[DATA_WIDTH-1:0];
assign val = data_out;
assign c_out = sum[DATA_WIDTH];
endmodule
module ym_dbg_read #(parameter DATA_WIDTH = 1)
(
input MCLK,
input c1,
input c2,
input prev,
input load,
input [DATA_WIDTH-1:0] load_val,
output next
);
wire [DATA_WIDTH-1:0] data_in;
wire [DATA_WIDTH-1:0] data_out;
ym_sr_bit_array #(.DATA_WIDTH(DATA_WIDTH)) mem
(
.MCLK(MCLK),
.c1(c1),
.c2(c2),
.inp(data_in),
.val(data_out)
);
wire [DATA_WIDTH-1:0] chain;
assign data_in = chain | (load ? load_val : {DATA_WIDTH{1'h0}});
generate
if (DATA_WIDTH == 1)
assign chain = prev;
else
assign chain = { prev, data_out[DATA_WIDTH-1:1] };
endgenerate
assign next = data_out[0];
endmodule
module ym_dbg_read_eg #(parameter DATA_WIDTH = 1)
(
input MCLK,
input c1,
input c2,
input prev,
input load,
input [DATA_WIDTH-1:0] load_val,
output next
);
wire [DATA_WIDTH-1:0] data_in;
wire [DATA_WIDTH-1:0] data_out;
ym_sr_bit_array #(.DATA_WIDTH(DATA_WIDTH)) mem
(
.MCLK(MCLK),
.c1(c1),
.c2(c2),
.data_in(data_in),
.data_out(data_out)
);
wire [DATA_WIDTH-1:0] chain;
assign data_in = chain | (load ? load_val : {DATA_WIDTH{1'h0}});
generate
if (DATA_WIDTH == 1)
assign chain = prev;
else
assign chain = { data_out[DATA_WIDTH-2:0], prev };
endgenerate
assign next = data_out[DATA_WIDTH-1];
endmodule
module ym_slatch_r #(parameter DATA_WIDTH = 1)
(
input MCLK,
input en,
input rst,
input [DATA_WIDTH-1:0] inp,
output [DATA_WIDTH-1:0] val,
output [DATA_WIDTH-1:0] nval
);
reg [DATA_WIDTH-1:0] mem = {DATA_WIDTH{1'h0}};
wire [DATA_WIDTH-1:0] mem_assign = rst ? {DATA_WIDTH{1'h0}} : (en ? inp : mem);
always @(posedge MCLK)
begin
mem <= mem_assign;
end
assign val = mem;
assign nval = ~mem;
endmodule