abstractaccelerator/opene906/smart_run/logical/uart/uart_trans.v

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2022-02-21 18:41:54 +08:00
/*Copyright 2020-2021 T-Head Semiconductor Co., Ltd.
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/
// &ModuleBeg; @22
module uart_trans(
ctrl_trans_data_length,
ctrl_trans_parity_bit,
ctrl_trans_parity_en,
ctrl_trans_shift_data,
ctrl_trans_stop_length,
ctrl_trans_thr_vld,
rst_b,
s_out,
sys_clk,
trans_clk_en,
trans_ctrl_busy,
trans_ctrl_thr_read,
trans_ctrl_thsr_empty
);
// &Ports; @23
input [1:0] ctrl_trans_data_length;
input ctrl_trans_parity_bit;
input ctrl_trans_parity_en;
input [7:0] ctrl_trans_shift_data;
input ctrl_trans_stop_length;
input ctrl_trans_thr_vld;
input rst_b;
input sys_clk;
input trans_clk_en;
output s_out;
output trans_ctrl_busy;
output trans_ctrl_thr_read;
output trans_ctrl_thsr_empty;
// &Regs; @24
reg [2:0] conter;
reg [4:0] cur_state;
reg [4:0] next_state;
reg parity_cout;
reg s_out;
reg thsr_empty;
reg trans_ctrl_thr_read;
reg [7:0] trans_shift_reg;
// &Wires; @25
wire [1:0] ctrl_trans_data_length;
wire ctrl_trans_parity_bit;
wire ctrl_trans_parity_en;
wire [7:0] ctrl_trans_shift_data;
wire ctrl_trans_stop_length;
wire ctrl_trans_thr_vld;
wire data_over;
wire parity_bit;
wire rst_b;
wire stop_over;
wire sys_clk;
wire thsr_shift_over;
wire thsr_wen;
wire trans_clk_en;
wire trans_ctrl_busy;
wire trans_ctrl_thsr_empty;
wire trans_enable;
parameter IDLE = 5'b00001,
START = 5'b00010,
DATA = 5'b00100,
PARITY = 5'b01000,
STOP = 5'b10000;
always@(posedge sys_clk or negedge rst_b)
begin
if(!rst_b)
cur_state[4:0] <= IDLE;
else if(trans_clk_en)
cur_state[4:0] <= next_state[4:0];
end
assign trans_enable = !thsr_empty;
// &CombBeg; @44
always @( parity_bit
or stop_over
or cur_state[4:0]
or trans_enable
or ctrl_trans_parity_en
or trans_shift_reg[0]
or data_over
or thsr_wen)
begin
s_out = 1'b1;
next_state[4:0] = IDLE;
case(cur_state[4:0])
IDLE:
begin
if(trans_enable)
next_state[4:0] = START;
end
START:
begin
s_out = 1'b0;
next_state[4:0] = DATA;
end
DATA:
begin
s_out = trans_shift_reg[0];
if(data_over)
next_state[4:0] = ctrl_trans_parity_en ? PARITY : STOP;
else
next_state[4:0] = DATA;
end
PARITY:
begin
s_out = parity_bit;
next_state[4:0] = STOP;
end
STOP:
begin
s_out = 1'b1;
if(stop_over)
begin
if(thsr_wen)
next_state[4:0] = START;
else
next_state[4:0] = IDLE;
end
else
next_state[4:0] = STOP;
end
default: next_state[4:0] = IDLE;
endcase
// &CombEnd; @87
end
always@(posedge sys_clk or negedge rst_b)
begin
if(!rst_b)
conter[2:0] <= 2'b0;
else if(trans_clk_en)
begin
if(data_over || stop_over)
conter[2:0] <= 2'b0;
else if((cur_state[2]) ||(cur_state[4]))
conter[2:0] <= conter[2:0] + 1'b1;
end
end
assign data_over = (conter[2:0] == {1'b1,ctrl_trans_data_length[1:0]});
assign stop_over = (cur_state[4]) && (conter[2:0] == {2'b0,ctrl_trans_stop_length});
//==============================================================
// generate the signal to ctrl
//==============================================================
assign trans_ctrl_busy = !(cur_state[0]);
//always @(posedge trans_clk or negedge rst_b)
//begin
// if(!rst_b)
// stop_state_latch <= 1'b0;
// else
// stop_state_latch <= cur_state[4];
//end
assign thsr_shift_over = cur_state[4];
//assign trans_ctrl_shiftreg_over = thsr_shift_over;
//==============================================================
// generate the output s_out signal
//==============================================================
always@(posedge sys_clk or negedge rst_b)
begin
if( !rst_b )
trans_shift_reg[7:0] <= 8'b0;
else if(trans_clk_en)
begin
if((cur_state[2]))
trans_shift_reg[7:0] <= {1'b0,trans_shift_reg[7:1]};
else if(thsr_wen)
trans_shift_reg[7:0] <= ctrl_trans_shift_data[7:0];
end
end
always@(posedge sys_clk or negedge rst_b)
begin
if( !rst_b )
thsr_empty <= 1'b1;
else if(trans_clk_en)
begin
if( thsr_wen )
thsr_empty <= 1'b0;
else if(thsr_shift_over)
thsr_empty <= 1'b1;
end
end
assign thsr_wen = ctrl_trans_thr_vld && ( thsr_shift_over || thsr_empty);
always@(posedge sys_clk or negedge rst_b)
begin
if( !rst_b )
trans_ctrl_thr_read <= 1'b0;
else if(trans_clk_en)
begin
if( thsr_wen )
trans_ctrl_thr_read <= 1'b1;
else
trans_ctrl_thr_read <= 1'b0;
end
end
assign trans_ctrl_thsr_empty = thsr_empty;
always@(posedge sys_clk or negedge rst_b)
begin
if( !rst_b )
parity_cout <= 1'b0;
else if(trans_clk_en)
begin
if(cur_state[1])
parity_cout <= 1'b0;
else if( (cur_state[2]))
parity_cout <= parity_cout ^ trans_shift_reg[0];
end
end
assign parity_bit = ~(parity_cout ^ ctrl_trans_parity_bit);
// &ModuleEnd; @180
endmodule