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[/] [tinyvliw8/] [trunk/] [src/] [vhdl/] [spiMaster.vhd] - Blame information for rev 5

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1 2 steckol
--
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-- SPI master module for 32 bit processor               kth @ IHP Dec. 2006
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--
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-- This VHDL ENTITY implements an SPI interface master core to be connected 
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-- to a microprocessor. It occupies 4 registers of 32 bit width in the address 
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-- space for the following functions:
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--
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--      addr 0 write:   write data to SPI interface and read at the same time
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--      addr 0 read:    get last received SPI data word
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--      addr 1 write:   set number of data bits in SPI word (bit 4:0)
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--      addr 1 read:    bit 4-0: number of data bits in SPI word -1
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--      addr 2 write:   set clock prescaler max. value (bit 3:0)
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--      addr 2 read:    bit 4-0: clock prescaler maximum value
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--      addr 3 write:   bit 0: SCK clock mode selector (see below)
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--                     bit 1: SPI shift+strobe edge selector (see below)
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--                     bit 2: SS active level selector (see below)
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--      addr 3 read:    bit 0: SCK clock mode selector (see below)
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--                     bit 1: SPI shift+strobe edge selector (see below)
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--                     bit 2: SS active level selector (see below)
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--                     bit 13-8: current clock prescaler (counter) value
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--                     bit 22-16: current state (shift) counter 
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--                     bit 31: operation completed, high active
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--
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-- The output port "intr" is equivalent to status bit 31 and can be used for 
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-- an interrupt to the processor on completion of a data transfer. 
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-- The bit is cleared when a new transfer starts. 
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-- The core averages all input (MISO) bits before shifting them into the input 
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-- data register. For this purpose the design countains an accumulator, which 
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-- is cleared on every "shifting" edge of the SPI clock SCK. Then, it strobes 
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-- the MISO input on every rising edge og teh primary clock. Finally, the 
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-- accumulated sum is compared with the clock prescaler value to make a 
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-- majority decision whether the bit is high or low. 
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--
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-- Configurable parameters of SPI master core:
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--
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--   number of data bits in SPI word (addr 1, bit 4-0, default value = 7): 
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--      The parameter gives the number of data bits - 1, which will be sent 
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--      and received when writing a word to address 0. The parameter's range 
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--      is 0 - 31, which corresponds to 1 - 32 bit. 
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--   clock prescaler max. value (addr 2, bit 3-0, default value = 3): 
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--      The parameter gives the max. count value of a prescaler to generate 
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--      the SPI clock signal SCK from input clock. The prescaler completely 
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--      expires in every half SCK cycle (high / low). The parameter's range 
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--      is 1(!) - 15, which corresponds to a divider ratio of 1:4 - 1:32. 
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--   SCK clock mode selector (addr 3, bit 0, default value = low): 
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--      low : SCK is low  in idle phases, first edge is a rising  edge
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--      high: SCK is high in idle phases, first edge is a falling edge
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--   SPI shift+strobe edge selector (addr 3, bit 1, default value = low): 
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--      low : first  (and all odd)  SCK edges strobe the MOSI and MISO values
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--            second (and all even) shift the data word to the next bit
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--      high: first  (and all odd)  shift the data word to the next bit
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--            second (and all even) SCK edges strobe the MOSI and MISO values
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--   SS active level selector (addr 3, bit 2, default value = low): 
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--      low : SS (slave select) output is low active (high in idle phases)
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--      high: SS (slave select) output is high active (low in idle phases)
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LIBRARY ieee;
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USE ieee.std_logic_1164.all;
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USE     ieee.numeric_std.all;
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ENTITY SPImaster IS
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  PORT (
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        inclk : IN  STD_LOGIC;  -- system clock
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        rst_n : IN  STD_LOGIC;  -- synchr. system reset, high active
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-- processor interface
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        we_n  : IN  STD_LOGIC;  -- write enable, low active
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        re_n  : IN  STD_LOGIC;  -- read  enable, low active
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        addr  : IN  STD_LOGIC_VECTOR(1 DOWNTO 0); -- address from processor
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        din   : IN  STD_LOGIC_VECTOR(7 DOWNTO 0);-- data from processor
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        dout  : OUT STD_LOGIC_VECTOR(7 DOWNTO 0);-- async. data to processor
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        intr  : OUT STD_LOGIC;  -- interrupt to processor, high active
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        intra : IN STD_LOGIC;   -- interrupt acknowledge
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-- SPI interface
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        SCK  : OUT STD_LOGIC;   -- SPI clock
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        SS   : OUT STD_LOGIC;   -- SPI slave select, active level configurable
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        MOSI : OUT STD_LOGIC;   -- SPI master output, slave input
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        MISO : IN  STD_LOGIC    -- SPI master input, slave output
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  );
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END SPImaster;
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ARCHITECTURE behav OF SPImaster IS
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  SIGNAL busy_s  : STD_LOGIC;            -- transfer active
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  SIGNAL irqEn   : STD_LOGIC;            -- interrupt enable
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  SIGNAL enable  : STD_LOGIC;            -- enable spi
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  SIGNAL clkmode : STD_LOGIC;            -- low: SCK starts with rising edge
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  SIGNAL bitmode : STD_LOGIC;            -- low: strobe at 1st SCK edge, shift at 2nd edge
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  SIGNAL sslevel : STD_LOGIC;            -- active level of SS output signal
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  signal ssmode  : std_logic;            -- automatic SS output signal
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  SIGNAL prsc    : UNSIGNED(4 DOWNTO 0); -- clock prescaler counter
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  SIGNAL bits    : UNSIGNED(2 DOWNTO 0); -- number of bits in SPI word
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  SIGNAL words   : unsigned(4 downto 0); -- number of SPI words in single transfer
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  SIGNAL clkcnt : UNSIGNED(prsc'LENGTH-1 DOWNTO 0);-- clock counter within one bit
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  SIGNAL bitcnt : UNSIGNED(bits'LENGTH+1 DOWNTO 0);-- state machine / bit counter
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  SIGNAL data : STD_LOGIC_VECTOR(7 DOWNTO 0);    -- internal data shift register
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  SIGNAL accu : STD_LOGIC_VECTOR(7 DOWNTO 0);   -- accumulator to MISO values
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  SIGNAL bitcntmax : UNSIGNED(bitcnt'LENGTH-1 DOWNTO 0);-- tmp. variable
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  signal fin_s  : std_logic;
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  signal cs_s   : std_logic;
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  signal mosi_s : std_logic;
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  SIGNAL fin_clk : std_logic;
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  SIGNAL clk : std_logic;
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  SIGNAL sclk_s : std_logic;
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BEGIN
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        bitcntmax <= Shift_Left(RESIZE(bits, bitcntmax'LENGTH), 1) + 4;
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        clk <= not(inclk) when enable = '1' and rst_n = '1' else
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               '0';
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  PROCESS (rst_n, we_n)                 -- SPI config. registers
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    BEGIN
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        IF rst_n = '0' THEN
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          clkmode <= '0';
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          bitmode <= '0';
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          sslevel <= '0';
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          ssmode  <= '0';
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          enable  <= '0';
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          irqEn   <= '0';
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          prsc    <= "00011";
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          bits    <= "111";
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          words   <= "00001";
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          data    <= (others => '0');
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        ELSIF (we_n'event and we_n = '0') THEN
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                if (re_n = '0') then
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                        if (addr = "00" and bitcnt = bitcntmax and clkcnt = prsc) then
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                                data <= din;
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                                if (words /= "00000") then
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                                        words <= words - 1;
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                                end if;
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                        else
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                                CASE addr IS
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                                WHEN "11" => clkmode <= din(0);
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                              bitmode <= din(1);
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                              sslevel <= din(2);
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                                          ssmode  <= din(3);
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                              irqEn   <= din(6);
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                              enable  <= din(7);
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                                WHEN "10" => prsc <= UNSIGNED(din(4 DOWNTO 0));
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                                WHEN "01" => words <= UNSIGNED(din(7 DOWNTO 3));
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                                         bits <= UNSIGNED(din(2 DOWNTO 0));
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                                WHEN OTHERS => NULL;
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                                END CASE;
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                        end if;
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                end if;
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        END IF;
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  END PROCESS;
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        fin_clk <= '1' when bitcnt = 0 and clkcnt = 0 else
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                   '1' when re_n = '0' and we_n = '0' and addr = "00" else
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                   '0';
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        process (rst_n, fin_clk)
162
        begin
163
                if (rst_n = '0') then
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                        fin_s <= '1';
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                else
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                        if (fin_clk'event and fin_clk = '1') then
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                                if (re_n = '0' and we_n = '0' and addr = "00") then
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                                        fin_s <= '0';
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                                else
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                                        fin_s <= '1';
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                                end if;
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                        end if;
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                end if;
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        end process;
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        cnt_p : process (rst_n, clk)
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        begin
178
                if (rst_n = '0') then
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                        bitcnt <= (others => '1');
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                        clkcnt <= (others => '1');
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                        -- bitcnt <= bitcntmax;
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                        -- clkcnt <= prsc;
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                else
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                        IF clk'EVENT AND clk='0' THEN
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                                if (fin_s = '0') then
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                                        IF clkcnt /= 0 THEN
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                                                clkcnt <= clkcnt - 1;
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                                        ELSIF bitcnt /= 0 THEN
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                                                bitcnt <= bitcnt - 1;
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                                        end if;
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                                else
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                                        bitcnt <= bitcntmax;
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                                        clkcnt <= prsc;
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                                end if;
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                        end if;
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                end if;
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        end process;
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        busy_flag_p : PROCESS (rst_n, clk)                      -- signals generated from state machine
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        BEGIN
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                IF rst_n = '0' THEN
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                        busy_s <= '0';
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                ELSIF clk'EVENT AND clk = '1' THEN
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                        if (fin_s = '0') then
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                                IF clkcnt = 0 and bitcnt = 1 THEN
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                                        busy_s <= '0';
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                                else
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                                        busy_s <= '1';
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                                END IF;
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                        else
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                                busy_s <= '0';
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                        END IF;
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                END IF;
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        END PROCESS;
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        cs_gen_p : process (rst_n, busy_s)
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        begin
218
                if (rst_n = '0') then
219
                        cs_s <= '1';
220
                else
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                        if (busy_s'event and busy_s = '1') then
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                                if (words = "00000") then
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                                        cs_s <= '1';
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                                else
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                                        cs_s <= '0';
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                                end if;
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                        end if;
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                end if;
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        end process;
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231
        SS <= 'Z'          when enable = '0' else
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              not(sslevel) when ssmode = '1' and (cs_s = '1' and busy_s = '0') else
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              sslevel;
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        PROCESS (rst_n, clk)
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        BEGIN
237
                if (rst_n = '0') then
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                        sclk_s <= '0';
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                        accu   <= (others => '0');
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                        mosi_s   <= '0';
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                ELSIF clk'EVENT AND clk='1' THEN
242
                        IF clkcnt /= 0 THEN
243
                                NULL;
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                        ELSIF bitcnt > 1 AND bitcnt < bitcntmax THEN
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                                sclk_s <= clkmode XOR bitcnt(0);
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247
                                if ((bitmode = '0' and sclk_s = not(clkmode)) or (bitmode = '1' and sclk_s = clkmode)) then
248
                                        if (bitmode = '0') then
249
                                                mosi_s <= accu(To_Integer(bits));
250
                                        else
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                                                mosi_s <= accu(To_Integer(bits));
252
                                        end if;
253
                                else
254
                                        accu <= accu(6 downto 0) & MISO;
255
                                end if;
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                        ELSE
257
                                sclk_s <= clkmode;
258
 
259
                                if (fin_s = '0' and bitcnt = bitcntmax) then
260
                                        accu <= data;
261
                                        mosi_s <= data(To_Integer(bits));
262
                                end if;
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                        END IF;
264
                END IF;
265
        END PROCESS;
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267
        MOSI <= mosi_s when enable = '1' else
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                'Z';
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        SCK  <= sclk_s when enable = '1' else
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                'Z';
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272
        irq_gen : process(enable, irqEn, clk)
273
        begin
274
                IF (enable = '0' and irqEn = '0') THEN
275
                         intr <= '0';
276
                ELSE
277
                        if (clk'EVENT AND clk = '0') THEN
278
                                if (intra = '1') then
279
                                        intr <= '0';
280
                                else
281
                                        if fin_s = '1' and bitcnt = 0 and clkcnt = 0 then
282
                                                intr <= '1';
283
                                        end if;
284
                                end if;
285
                        end if;
286
                end if;
287
        end process;
288
 
289
        WITH addr SELECT dout <=
290
                accu                                                               WHEN "00",
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                std_logic_vector(words) & STD_LOGIC_VECTOR(bits)                   WHEN "01",
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                STD_LOGIC_VECTOR(RESIZE(prsc,dout'LENGTH))                         WHEN "10",
293
                enable & irqEn & '0' & busy_s & ssmode & sslevel & bitmode & clkmode WHEN OTHERS;
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END behav;

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