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[/] [ion/] [trunk/] [vhdl/] [SoC/] [uart.vhdl] - Rev 242
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--############################################################################## -- uart.vhdl -- Basic, hardwired RS232 UART. -- -- Most operational parameters are hardcoded: 8 bit words, no parity, 1 stop -- bit. The only parameter that can be configured in run time is the baud rate. -- -- The receiver logic is a simplified copy of the 8051 UART. The bit period is -- split in 16 sampling periods, and 3 samples are taken at the center of each -- bit period. The bit value is decided by majority. The receiver logic has some -- error recovery capability that should make this core reliable enough for -- actual application use -- yet, the core does not have a format test bench. -- -- See usage notes below. -- -------------------------------------------------------------------------------- -- This file is free software (See COPYING.TXT) --############################################################################## library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; -------------------------------------------------------------------------------- -- UART programmer model -------------------------------------------------------------------------------- -- -- The UART has a number of configuration registers addressable with input -- signal addr_*_i: -- -- [00] => Data buffer, both transmission and reception. -- [01] => Status/control register (r/w). -- [10] => Bit period register, low byte. -- [11] => Bit period register, high byte. -- -- -- Data buffers: ---------------- -- -- The same address [00b] is used for both the receive buffer and the -- transmision buffer. -- -- Writing to the data buffer when flag TxRdy is high will trigger a -- transmission and clear flag TxRdy. -- Writing to the data buffer when flag TxRdy is clear will have no effect. -- -- Reading the data register when flag RxRdy is high will return the last -- received data byte, and will clear flag RxRdy but NOT RxIrq. -- Reading the register when flag RxRdy is clear will return indeterminate data, -- which in practice will usually be the last byte received. -- -- Interrupts: -------------- -- -- The core has two interrupt sources tied to a single external irq line. The -- sources are these: -- -- -# Receiver interrupt: Raised when the stop bit is sampled and determined -- to be valid (about the middle of the bit period). -- If the stop bit is not valid (not high) then the interrupt is not -- triggered. If a start bit is determined to be spurious (i.e. the falling -- edge is detected but the bit value when sampled is not 0) then the -- interrupt is not triggered. -- This interrupt sets flag RxIrw in the status register. -- -# Transmitter interrupt: Raised at the end of the transmission of the stop -- bit. -- This interrupt sets flag TxIrq in the status register 1 clock cycle after -- the interrupt is raised. -- -- The core does not have any interrupt enable mask. If any interrupt source -- triggers, the output irq_o is asserted for one cycle. This is all the extent -- of the interrupt processing done by this module. -- -- Error detection: ------------------- -- -- The core is capable of detecting and recovering from these error conditions: -- -- -# When a start bit is determined to be spurious (i.e. the falling edge is -- detected but the bit value when sampled is not 0) then the core returns to -- its idle state (waiting for a new start bit). -- -# If a stop bit is determined to be invalid (not 1 when sampled), the -- reception interrupt is not triggered and the received byte is discarded. -- -# When the 3 samples taken from the center of a bit period are not equal, -- the bit value is decided by majority. -- -- In none of the 3 cases does the core raise any error flag. It would be very -- easy to include those flags in the core, but it would take a lot more time -- to test them minimally and that's why they haven't been included. -- -- Status register flags: ------------------------- -- -- 7 6 5 4 3 2 1 0 -- +-------+-------+-------+-------+-------+-------+-------+-------+ -- | 0 | 0 | RxIrq | TxIrq | 0 | 0 | RxRdy | TxRdy | -- +-------+-------+-------+-------+-------+-------+-------+-------+ -- h h W1C W1C h h r r -- -- Bits marked 'h' are hardwired and can't be modified. -- Bits marked 'r' are read only; they are set and clear by the UART core. -- Bits marked W1C ('Write 1 Clear') are set by the UART core when an interrupt -- has been triggered and must be cleared by the software by writing a '1'. -- -- -# Status bit TxRdy is high when there isn't any transmission in progress. -- It is cleared when data is written to the transmission buffer and is -- raised at the same time the transmission interrupt is triggered. -- -# Status bit RxRdy is raised at the same time the receive interrupt is -- triggered and is cleared when the data register is read. -- -# Status bit TxIrq is raised when the transmission interrupt is triggered -- and is cleared when a 1 is written to it. -- -# Status bit RxIrq is raised when the reception interrupt is triggered -- and is cleared when a 1 is written to it. -- -- When writing to the status/control registers, only flags TxIrq and RxIrq are -- affected, and only when writing a '1' as explained above. All other flags -- are read-only. -- -- Baud rate configuration: --------------------------- -- -- The baud rate is determined by the value of 14-bit register 'bit_period_reg'. -- This register holds the length of the bit period in clock cycles and its -- value may be hardcoded or configured at run time. -- -- When generic HARDWIRED is true, bit_period_reg is hardwired with a value -- computed from the value of generic BAUD_RATE. The bit period computation -- needs to know the master clock rate, which should be given in generic -- CLOCK_RATE. -- Writes to the baud registers when HARDWIRED is true will be ignored. -- -- When generic HARDWIRED is false, generics BAUD_RATE and CLOCK_RATE determine -- the reset value of bit_period_reg, but the register can be changed at run -- time by writing at addresses [10b] and [11b], which access the low and high -- bytes of the register, respectively. -- Reading from those register addresses returns the value of the status -- register (a LUT saving measure) so the registers are effectively write-only. -- -------------------------------------------------------------------------------- -- Core interface signals: -- -- clk_i: Clock input, active rising edge. -- reset_i: Synchronous reset. -- txd_o: TxD UART output. -- rxd_i: RxD UART input -- synchronization logic included. -- irq_o: Interrupt output, asserted for 1 cycle when triggered. -- data_i: Data bus, input. -- data_o: Data bus, output. -- addr_rd_i: Register selection address, read access (see above). -- addr_wr_i: Register selection address, write access (see above). -- wr_i: Write enable input. -- rd_i: Read enable input. -- ce_i: Chip enable, must be active at the same time as wr_i or rd_i. -- -- -- No detailed explanation of the i/f timing can be given for lack of time. -- The core reads and writes like a synchronous memory. -------------------------------------------------------------------------------- entity uart is generic ( HARDWIRED : boolean := true; -- Baud rate hardwired to constant value BAUD_RATE : integer := 19200; -- Default (or hardwired) baud rate CLOCK_FREQ : integer := 50E6); -- Clock rate port ( rxd_i : in std_logic; txd_o : out std_logic; irq_o : out std_logic; data_i : in std_logic_vector(7 downto 0); data_o : out std_logic_vector(7 downto 0); addr_rd_i : in std_logic_vector(1 downto 0); addr_wr_i : in std_logic_vector(1 downto 0); wr_i : in std_logic; rd_i : in std_logic; ce_i : in std_logic; clk_i : in std_logic; reset_i : in std_logic); end uart; architecture hardwired of uart is -- Bit period expressed in master clock cycles constant DEFAULT_BIT_PERIOD : integer := (CLOCK_FREQ / BAUD_RATE); -- Bit sampling period is 1/16 of the baud rate. constant DEFAULT_SAMPLING_PERIOD : integer := DEFAULT_BIT_PERIOD / 16; --############################################################################## -- Common signals signal reset : std_logic; signal clk : std_logic; signal bit_period_reg : unsigned(13 downto 0); signal sampling_period : unsigned(9 downto 0); -- Interrupt & status register signals signal tx_irq_flag : std_logic; signal rx_irq_flag : std_logic; signal load_stat_reg : std_logic; signal load_tx_reg : std_logic; -- Receiver signals signal rxd_q : std_logic; signal tick_ctr : unsigned(3 downto 0); signal state : unsigned(3 downto 0); signal next_state : unsigned(3 downto 0); signal start_bit_detected : std_logic; signal reset_tick_ctr : std_logic; signal stop_bit_sampled : std_logic; signal load_rx_buffer : std_logic; signal stop_error : std_logic; signal samples : std_logic_vector(2 downto 0); signal sampled_bit : std_logic; signal do_shift : std_logic; signal rx_buffer : std_logic_vector(7 downto 0); signal rx_shift_reg : std_logic_vector(9 downto 0); signal tick_ctr_enable : std_logic; signal tick_baud_ctr : unsigned(10 downto 0); signal rx_rdy_flag : std_logic; signal rx_irq : std_logic; signal set_rx_rdy_flag : std_logic; signal rxd : std_logic; signal read_rx : std_logic; signal status : std_logic_vector(7 downto 0); -- Transmitter signals signal tx_counter : unsigned(13 downto 0); signal tx_data : std_logic_vector(10 downto 0); signal tx_ctr_bit : unsigned(3 downto 0); signal tx_busy : std_logic; signal tx_irq : std_logic; begin -- Rename the most commonly used inputs to get rid of the i/o suffix clk <= clk_i; reset <= reset_i; rxd <= rxd_i; -- Serial port status byte -- only 2 status flags status <= "00" & rx_irq_flag & tx_irq_flag & -- Interrupt flags "00" & rx_rdy_flag & (not tx_busy); -- State flags -- Read register multiplexor with addr_rd_i select data_o <= rx_buffer when "00", status when others; load_tx_reg <= '1' when wr_i = '1' and ce_i = '1' and addr_wr_i = "00" else '0'; load_stat_reg <= '1' when wr_i = '1' and ce_i = '1' and addr_wr_i = "01" else '0'; read_rx <= '1' when rd_i = '1' and ce_i = '1' and addr_rd_i = "00" else '0'; rx_irq <= set_rx_rdy_flag; irq_o <= rx_irq or tx_irq; interrupt_flags: process(clk) begin if clk'event and clk='1' then if reset = '1' then rx_irq_flag <= '0'; tx_irq_flag <= '0'; else if set_rx_rdy_flag='1' then rx_irq_flag <= '1'; elsif load_stat_reg='1' and data_i(5)='1' then rx_irq_flag <= '0'; end if; if tx_irq='1' then tx_irq_flag <= '1'; elsif load_stat_reg='1' and data_i(4)='1' then tx_irq_flag <= '0'; end if; end if; end if; end process interrupt_flags; baud_rate_registers: process(clk) begin if clk'event and clk='1' then if reset = '1' then bit_period_reg <= to_unsigned(DEFAULT_BIT_PERIOD,14); else if wr_i = '1' and ce_i = '1' then if addr_wr_i = "10" then bit_period_reg(7 downto 0) <= unsigned(data_i); elsif addr_wr_i = "11" then bit_period_reg(13 downto 8) <= unsigned(data_i(5 downto 0)); end if; end if; end if; end if; end process baud_rate_registers; sampling_period <= bit_period_reg(13 downto 4); -- Receiver -------------------------------------------------------------------- baud_counter: process(clk) begin if clk'event and clk='1' then if reset='1' then tick_baud_ctr <= (others => '0'); else if tick_baud_ctr=sampling_period then tick_baud_ctr <= (others => '0'); else tick_baud_ctr <= tick_baud_ctr + 1; end if; end if; end if; end process baud_counter; tick_ctr_enable<= '1' when tick_baud_ctr=sampling_period else '0'; -- Register RxD at the bit sampling rate -- 16 times the baud rate. rxd_input_register: process(clk) begin if clk'event and clk='1' then if reset='1' then rxd_q <= '0'; else if tick_ctr_enable='1' then rxd_q <= rxd; end if; end if; end if; end process rxd_input_register; -- We detect the start bit when... start_bit_detected <= '1' when state="0000" and -- ...we're waiting for the start bit... rxd_q='1' and rxd='0' -- ...and we see RxD going 1-to-0 else '0'; -- As soon as we detect the start bit we synchronize the bit sampler to -- the start bit's falling edge. reset_tick_ctr <= '1' when start_bit_detected='1' else '0'; -- We have seen the end of the stop bit when... stop_bit_sampled <= '1' when state="1010" and -- ...we're in the stop bit period... tick_ctr="1011" -- ...and we get the 11th sample in the bit period else '0'; -- Load the RX buffer with the shift register when... load_rx_buffer <= '1' when stop_bit_sampled='1' and -- ...we've just seen the end of the stop bit... sampled_bit='1' -- ...and its value is correct (1) else '0'; -- Conversely, we detect a stop bit error when... stop_error <= '1' when stop_bit_sampled='1' and -- ...we've just seen the end of the stop bit... sampled_bit='0' -- ...and its value is incorrect (0) else '0'; -- tick_ctr is a counter 16 times faster than the baud rate that is aligned to -- the falling edge of the start bit, so that when tick_ctr=0 we're close to -- the start of a bit period. bit_sample_counter: process(clk) begin if clk'event and clk='1' then if reset='1' then tick_ctr <= "0000"; else if tick_ctr_enable='1' then -- Restart counter when it reaches 15 OR when the falling edge -- of the start bit is detected; this is how we synchronize to the -- start bit. if tick_ctr="1111" or reset_tick_ctr='1' then tick_ctr <= "0000"; else tick_ctr <= tick_ctr + 1; end if; end if; end if; end if; end process bit_sample_counter; -- Main RX state machine: -- 0 -> waiting for start bit -- 1 -> sampling start bit -- 2..9 -> sampling data bit 0 to 7 -- 10 -> sampling stop bit next_state <= -- Start sampling the start bit when we detect the falling edge "0001" when state="0000" and start_bit_detected='1' else -- Return to idle state if the start bit is not a clean 0 "0000" when state="0001" and tick_ctr="1010" and sampled_bit='1' else -- Return to idle state at the end of the stop bit period "0000" when state="1010" and tick_ctr="1111" else -- Otherwise, proceed to next bit period at the end of each period state + 1 when tick_ctr="1111" and do_shift='1' else state; rx_state_machine_register: process(clk) begin if clk'event and clk='1' then if reset='1' then state <= "0000"; else if tick_ctr_enable='1' then state <= next_state; end if; end if; end if; end process rx_state_machine_register; -- Collect 3 RxD samples from the 3 central sampling periods of the bit period. rx_sampler: process(clk) begin if clk'event and clk='1' then if reset='1' then samples <= "000"; else if tick_ctr_enable='1' then if tick_ctr="0111" then samples(0) <= rxd; end if; if tick_ctr="1000" then samples(1) <= rxd; end if; if tick_ctr="1001" then samples(2) <= rxd; end if; end if; end if; end if; end process rx_sampler; -- Decide the value of the RxD bit by majority with samples select sampled_bit <= '0' when "000", '0' when "001", '0' when "010", '1' when "011", '0' when "100", '1' when "101", '1' when "110", '1' when others; rx_buffer_register: process(clk) begin if clk'event and clk='1' then if reset='1' then rx_buffer <= "00000000"; set_rx_rdy_flag <= '0'; else if tick_ctr_enable='1' and load_rx_buffer='1' and rx_rdy_flag='0' then rx_buffer <= rx_shift_reg(8 downto 1); set_rx_rdy_flag <= '1'; else set_rx_rdy_flag <= '0'; end if; end if; end if; end process rx_buffer_register; rx_flag: process(clk) begin if clk'event and clk='1' then if reset='1' then rx_rdy_flag <= '0'; else if set_rx_rdy_flag='1' then rx_rdy_flag <= '1'; else if read_rx = '1' then rx_rdy_flag <= '0'; end if; end if; end if; end if; end process rx_flag; -- RX shifter control: shift in any state other than idle state (0) do_shift <= state(0) or state(1) or state(2) or state(3); rx_shift_register: process(clk) begin if clk'event and clk='1' then if reset='1' then rx_shift_reg <= "1111111111"; else if tick_ctr_enable='1' then if tick_ctr="1010" and do_shift='1' then rx_shift_reg(9) <= sampled_bit; rx_shift_reg(8 downto 0) <= rx_shift_reg(9 downto 1); end if; end if; end if; end if; end process rx_shift_register; -- Transmitter ----------------------------------------------------------------- main_tx_process: process(clk) begin if clk'event and clk='1' then if reset='1' then tx_data <= "10111111111"; tx_busy <= '0'; tx_irq <= '0'; tx_ctr_bit <= "0000"; tx_counter <= (others => '0'); elsif load_tx_reg='1' and tx_busy='0' then tx_data <= "1"&data_i&"01"; tx_busy <= '1'; else if tx_busy='1' then if tx_counter = bit_period_reg then tx_counter <= (others => '0'); tx_data(9 downto 0) <= tx_data(10 downto 1); tx_data(10) <= '1'; if tx_ctr_bit = "1010" then tx_busy <= '0'; tx_irq <= '1'; tx_ctr_bit <= "0000"; else tx_ctr_bit <= tx_ctr_bit + 1; end if; else tx_counter <= tx_counter + 1; end if; else tx_irq <= '0'; end if; end if; end if; end process main_tx_process; txd_o <= tx_data(0); end hardwired;
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