| // SPDX-License-Identifier: Apache-2.0 |
| |
| module uart_rx #( |
| parameter CLKS_PER_BIT = 174 |
| )( |
| input i_Clock, |
| input i_Rx_Serial, |
| output o_Rx_DV, |
| output [7:0] o_Rx_Byte |
| ); |
| |
| parameter s_IDLE = 3'b000; |
| parameter s_RX_START_BIT = 3'b001; |
| parameter s_RX_DATA_BITS = 3'b010; |
| parameter s_RX_STOP_BIT = 3'b011; |
| parameter s_CLEANUP = 3'b100; |
| |
| reg r_Rx_Data_R = 1'b1; |
| reg r_Rx_Data = 1'b1; |
| |
| reg [7:0] r_Clock_Count = 0; |
| reg [2:0] r_Bit_Index = 0; //8 bits total |
| reg [7:0] r_Rx_Byte = 0; |
| reg r_Rx_DV = 0; |
| reg [2:0] r_SM_Main = 0; |
| |
| // Purpose: Double-register the incoming data. |
| // This allows it to be used in the UART RX Clock Domain. |
| // (It removes problems caused by metastability) |
| always @(posedge i_Clock) |
| begin |
| r_Rx_Data_R <= i_Rx_Serial; |
| r_Rx_Data <= r_Rx_Data_R; |
| end |
| |
| |
| // Purpose: Control RX state machine |
| always @(posedge i_Clock) |
| begin |
| |
| case (r_SM_Main) |
| s_IDLE : |
| begin |
| r_Rx_DV <= 1'b0; |
| r_Clock_Count <= 0; |
| r_Bit_Index <= 0; |
| |
| if (r_Rx_Data == 1'b0) // Start bit detected |
| r_SM_Main <= s_RX_START_BIT; |
| else |
| r_SM_Main <= s_IDLE; |
| end |
| |
| // Check middle of start bit to make sure it's still low |
| s_RX_START_BIT : |
| begin |
| if (r_Clock_Count == (CLKS_PER_BIT-1)/2) |
| begin |
| if (r_Rx_Data == 1'b0) |
| begin |
| r_Clock_Count <= 0; // reset counter, found the middle |
| r_SM_Main <= s_RX_DATA_BITS; |
| end |
| else |
| r_SM_Main <= s_IDLE; |
| end |
| else |
| begin |
| r_Clock_Count <= r_Clock_Count + 1; |
| r_SM_Main <= s_RX_START_BIT; |
| end |
| end // case: s_RX_START_BIT |
| |
| |
| // Wait CLKS_PER_BIT-1 clock cycles to sample serial data |
| s_RX_DATA_BITS : |
| begin |
| if (r_Clock_Count < CLKS_PER_BIT-1) |
| begin |
| r_Clock_Count <= r_Clock_Count + 1; |
| r_SM_Main <= s_RX_DATA_BITS; |
| end |
| else |
| begin |
| r_Clock_Count <= 0; |
| r_Rx_Byte[r_Bit_Index] <= r_Rx_Data; |
| |
| // Check if we have received all bits |
| if (r_Bit_Index < 7) |
| begin |
| r_Bit_Index <= r_Bit_Index + 1; |
| r_SM_Main <= s_RX_DATA_BITS; |
| end |
| else |
| begin |
| r_Bit_Index <= 0; |
| r_SM_Main <= s_RX_STOP_BIT; |
| end |
| end |
| end // case: s_RX_DATA_BITS |
| |
| |
| // Receive Stop bit. Stop bit = 1 |
| s_RX_STOP_BIT : |
| begin |
| // Wait CLKS_PER_BIT-1 clock cycles for Stop bit to finish |
| if (r_Clock_Count < CLKS_PER_BIT-1) |
| begin |
| r_Clock_Count <= r_Clock_Count + 1; |
| r_SM_Main <= s_RX_STOP_BIT; |
| end |
| else |
| begin |
| r_Rx_DV <= 1'b1; |
| r_Clock_Count <= 0; |
| r_SM_Main <= s_CLEANUP; |
| end |
| end // case: s_RX_STOP_BIT |
| |
| |
| // Stay here 1 clock |
| s_CLEANUP : |
| begin |
| r_SM_Main <= s_IDLE; |
| r_Rx_DV <= 1'b0; |
| end |
| |
| |
| default : |
| r_SM_Main <= s_IDLE; |
| |
| endcase |
| end |
| |
| assign o_Rx_DV = r_Rx_DV; |
| assign o_Rx_Byte = r_Rx_Byte; |
| |
| endmodule // uart_rx |