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[/] [i2c/] [trunk/] [rtl/] [vhdl/] [I2C.VHD] - Rev 74
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---- Simple I2C controller---- 1) No multimaster-- 2) No slave mode-- 3) No fifo's---- notes:-- Every command is acknowledged. Do not set a new command before previous is acknowledged.-- Dout is available 1 clock cycle later as cmd_ack--library ieee;use ieee.std_logic_1164.all;use ieee.std_logic_arith.all;package I2C iscomponent simple_i2c isport (clk : in std_logic;ena : in std_logic;nReset : in std_logic;clk_cnt : in unsigned(7 downto 0); -- 4x SCL-- input signalsstart,stop,read,write,ack_in : std_logic;Din : in std_logic_vector(7 downto 0);-- output signalscmd_ack : out std_logic;ack_out : out std_logic;Dout : out std_logic_vector(7 downto 0);-- i2c signalsSCL : inout std_logic;SDA : inout std_logic);end component simple_i2c;end package I2C;library ieee;use ieee.std_logic_1164.all;use ieee.std_logic_arith.all;entity simple_i2c isport (clk : in std_logic;ena : in std_logic;nReset : in std_logic;clk_cnt : in unsigned(7 downto 0); -- 4x SCL-- input signalsstart,stop,read,write,ack_in : std_logic;Din : in std_logic_vector(7 downto 0);-- output signalscmd_ack : out std_logic;ack_out : out std_logic;Dout : out std_logic_vector(7 downto 0);-- i2c signalsSCL : inout std_logic;SDA : inout std_logic);end entity simple_i2c;architecture structural of simple_i2c iscomponent i2c_core isport (clk : in std_logic;nReset : in std_logic;clk_cnt : in unsigned(7 downto 0);cmd : in std_logic_vector(2 downto 0);cmd_ack : out std_logic;busy : out std_logic;Din : in std_logic;Dout : out std_logic;SCL : inout std_logic;SDA : inout std_logic);end component i2c_core;-- commands for i2c_coreconstant CMD_NOP : std_logic_vector(2 downto 0) := "000";constant CMD_START : std_logic_vector(2 downto 0) := "010";constant CMD_STOP : std_logic_vector(2 downto 0) := "011";constant CMD_READ : std_logic_vector(2 downto 0) := "100";constant CMD_WRITE : std_logic_vector(2 downto 0) := "101";-- signals for i2c_coresignal core_cmd : std_logic_vector(2 downto 0);signal core_ack, core_busy, core_txd, core_rxd : std_logic;-- signals for shift registersignal sr : std_logic_vector(7 downto 0); -- 8bit shift registersignal shift, ld : std_logic;-- signals for state machinesignal go, host_ack : std_logic;begin-- hookup i2c coreu1: i2c_core port map (clk, nReset, clk_cnt, core_cmd, core_ack, core_busy, core_txd, core_rxd, SCL, SDA);-- generate host-command-acknowledgecmd_ack <= host_ack;-- generate go-signalgo <= (read or write) and not host_ack;-- assign Dout output to shift-registerDout <= sr;-- assign ack_out output to core_rxd (contains last received bit)ack_out <= core_rxd;-- generate shift registershift_register: process(clk)beginif (clk'event and clk = '1') thenif (ld = '1') thensr <= din;elsif (shift = '1') thensr <= (sr(6 downto 0) & core_rxd);end if;end if;end process shift_register;---- state machine--statemachine : blocktype states is (st_idle, st_start, st_read, st_write, st_ack, st_stop);signal state : states;signal dcnt : unsigned(2 downto 0);begin---- command interpreter, translate complex commands into simpler I2C commands--nxt_state_decoder: process(clk, nReset, state)variable nxt_state : states;variable idcnt : unsigned(2 downto 0);variable ihost_ack : std_logic;variable icore_cmd : std_logic_vector(2 downto 0);variable icore_txd : std_logic;variable ishift, iload : std_logic;begin-- 8 databits (1byte) of data to shift-in/outidcnt := dcnt;-- no acknowledge (until command complete)ihost_ack := '0';icore_txd := core_txd;-- keep current command to i2c_coreicore_cmd := core_cmd;-- no shifting or loading of shift-registerishift := '0';iload := '0';-- keep current state;nxt_state := state;case state iswhen st_idle =>if (go = '1') thenif (start = '1') thennxt_state := st_start;icore_cmd := CMD_START;elsif (read = '1') thennxt_state := st_read;icore_cmd := CMD_READ;idcnt := "111";elsenxt_state := st_write;icore_cmd := CMD_WRITE;idcnt := "111";iload := '1';end if;end if;when st_start =>if (core_ack = '1') thenif (read = '1') thennxt_state := st_read;icore_cmd := CMD_READ;idcnt := "111";elsenxt_state := st_write;icore_cmd := CMD_WRITE;idcnt := "111";iload := '1';end if;end if;when st_write =>if (core_ack = '1') thenidcnt := dcnt -1; -- count down Data_countericore_txd := sr(7);if (dcnt = 0) thennxt_state := st_ack;icore_cmd := CMD_READ;elseishift := '1';-- icore_txd := sr(7);end if;end if;when st_read =>if (core_ack = '1') thenidcnt := dcnt -1; -- count down Data_counterishift := '1';if (dcnt = 0) thennxt_state := st_ack;icore_cmd := CMD_WRITE;icore_txd := ack_in;end if;end if;when st_ack =>if (core_ack = '1') then-- generate command acknowledge signalihost_ack := '1';-- Perform an additional shift, needed for 'read' (store last received bit in shift register)ishift := '1';-- check for stop; Should a STOP command be generated ?if (stop = '1') thennxt_state := st_stop;icore_cmd := CMD_STOP;elsenxt_state := st_idle;icore_cmd := CMD_NOP;end if;end if;when st_stop =>if (core_ack = '1') thennxt_state := st_idle;icore_cmd := CMD_NOP;end if;when others => -- illegal statesnxt_state := st_idle;icore_cmd := CMD_NOP;end case;-- generate registersif (nReset = '0') thencore_cmd <= CMD_NOP;core_txd <= '0';shift <= '0';ld <= '0';dcnt <= "111";host_ack <= '0';state <= st_idle;elsif (clk'event and clk = '1') thenif (ena = '1') thenstate <= nxt_state;dcnt <= idcnt;shift <= ishift;ld <= iload;core_cmd <= icore_cmd;core_txd <= icore_txd;host_ack <= ihost_ack;end if;end if;end process nxt_state_decoder;end block statemachine;end architecture structural;------ I2C Core---- Translate simple commands into SCL/SDA transitions-- Each command has 5 states, A/B/C/D/idle---- start: SCL ~~~~~~~~~~\____-- SDA ~~~~~~~~\______-- x | A | B | C | D | i---- repstart SCL ____/~~~~\___-- SDA __/~~~\______-- x | A | B | C | D | i---- stop SCL ____/~~~~~~~~-- SDA ==\____/~~~~~-- x | A | B | C | D | i----- write SCL ____/~~~~\____-- SDA ==X=========X=-- x | A | B | C | D | i----- read SCL ____/~~~~\____-- SDA XXXX=====XXXX-- x | A | B | C | D | i---- Timing: Normal mode Fast mode------------------------------------------------------------------- Fscl 100KHz 400KHz-- Th_scl 4.0us 0.6us High period of SCL-- Tl_scl 4.7us 1.3us Low period of SCL-- Tsu:sta 4.7us 0.6us setup time for a repeated start condition-- Tsu:sto 4.0us 0.6us setup time for a stop conditon-- Tbuf 4.7us 1.3us Bus free time between a stop and start condition--library ieee;use ieee.std_logic_1164.all;use ieee.std_logic_arith.all;entity i2c_core isport (clk : in std_logic;nReset : in std_logic;clk_cnt : in unsigned(7 downto 0);cmd : in std_logic_vector(2 downto 0);cmd_ack : out std_logic;busy : out std_logic;Din : in std_logic;Dout : out std_logic;SCL : inout std_logic;SDA : inout std_logic);end entity i2c_core;architecture structural of i2c_core isconstant CMD_NOP : std_logic_vector(2 downto 0) := "000";constant CMD_START : std_logic_vector(2 downto 0) := "010";constant CMD_STOP : std_logic_vector(2 downto 0) := "011";constant CMD_READ : std_logic_vector(2 downto 0) := "100";constant CMD_WRITE : std_logic_vector(2 downto 0) := "101";type cmds is (idle, start_a, start_b, start_c, start_d, stop_a, stop_b, stop_c, rd_a, rd_b, rd_c, rd_d, wr_a, wr_b, wr_c, wr_d);signal state : cmds;signal SDAo, SCLo : std_logic;signal txd : std_logic;signal clk_en, slave_wait :std_logic;signal cnt : unsigned(7 downto 0) := clk_cnt;begin-- whenever the slave is not ready it can delay the cycle by pulling SCL lowslave_wait <= '1' when ((SCLo = '1') and (SCL = '0')) else '0';-- generate clk enable signalgen_clken: process(clk, nReset)beginif (nReset = '0') thencnt <= (others => '0');clk_en <= '1'; --'0';elsif (clk'event and clk = '1') thenif (cnt = 0) thenclk_en <= '1';cnt <= clk_cnt;elseif (slave_wait = '0') thencnt <= cnt -1;end if;clk_en <= '0';end if;end if;end process gen_clken;-- generate statemachinenxt_state_decoder : process (clk, nReset, state, cmd, SDA)variable nxt_state : cmds;variable icmd_ack, ibusy, store_sda : std_logic;variable itxd : std_logic;beginnxt_state := state;icmd_ack := '0'; -- default no acknowledgeibusy := '1'; -- default busystore_sda := '0';itxd := txd;case (state) is-- idlewhen idle =>case cmd iswhen CMD_START =>nxt_state := start_a;icmd_ack := '1'; -- command completedwhen CMD_STOP =>nxt_state := stop_a;icmd_ack := '1'; -- command completedwhen CMD_WRITE =>nxt_state := wr_a;icmd_ack := '1'; -- command completeditxd := Din;when CMD_READ =>nxt_state := rd_a;icmd_ack := '1'; -- command completedwhen others =>nxt_state := idle;-- don't acknowledge NOP command icmd_ack := '1'; -- command completedibusy := '0';end case;-- startwhen start_a =>nxt_state := start_b;when start_b =>nxt_state := start_c;when start_c =>nxt_state := start_d;when start_d =>nxt_state := idle;ibusy := '0'; -- not busy when idle-- stopwhen stop_a =>nxt_state := stop_b;when stop_b =>nxt_state := stop_c;when stop_c =>-- nxt_state := stop_d;-- when stop_d =>nxt_state := idle;ibusy := '0'; -- not busy when idle-- readwhen rd_a =>nxt_state := rd_b;when rd_b =>nxt_state := rd_c;when rd_c =>nxt_state := rd_d;store_sda := '1';when rd_d =>nxt_state := idle;ibusy := '0'; -- not busy when idle-- writewhen wr_a =>nxt_state := wr_b;when wr_b =>nxt_state := wr_c;when wr_c =>nxt_state := wr_d;when wr_d =>nxt_state := idle;ibusy := '0'; -- not busy when idleend case;-- generate regsif (nReset = '0') thenstate <= idle;cmd_ack <= '0';busy <= '0';txd <= '0';Dout <= '0';elsif (clk'event and clk = '1') thenif (clk_en = '1') thenstate <= nxt_state;busy <= ibusy;txd <= itxd;if (store_sda = '1') thenDout <= SDA;end if;end if;cmd_ack <= icmd_ack and clk_en;end if;end process nxt_state_decoder;---- convert states to SCL and SDA signals--output_decoder: process (clk, nReset, state)variable iscl, isda : std_logic;begincase (state) iswhen idle =>iscl := SCLo; -- keep SCL in same stateisda := SDA; -- keep SDA in same state-- startwhen start_a =>iscl := SCLo; -- keep SCL in same state (for repeated start)isda := '1'; -- set SDA highwhen start_b =>iscl := '1'; -- set SCL highisda := '1'; -- keep SDA highwhen start_c =>iscl := '1'; -- keep SCL highisda := '0'; -- sel SDA lowwhen start_d =>iscl := '0'; -- set SCL lowisda := '0'; -- keep SDA low-- stopwhen stop_a =>iscl := '0'; -- keep SCL disabledisda := '0'; -- set SDA lowwhen stop_b =>iscl := '1'; -- set SCL highisda := '0'; -- keep SDA lowwhen stop_c =>iscl := '1'; -- keep SCL highisda := '1'; -- set SDA high-- writewhen wr_a =>iscl := '0'; -- keep SCL low-- isda := txd; -- set SDAisda := Din;when wr_b =>iscl := '1'; -- set SCL high-- isda := txd; -- set SDAisda := Din;when wr_c =>iscl := '1'; -- keep SCL high-- isda := txd; -- set SDAisda := Din;when wr_d =>iscl := '0'; -- set SCL low-- isda := txd; -- set SDAisda := Din;-- readwhen rd_a =>iscl := '0'; -- keep SCL lowisda := '1'; -- tri-state SDAwhen rd_b =>iscl := '1'; -- set SCL highisda := '1'; -- tri-state SDAwhen rd_c =>iscl := '1'; -- keep SCL highisda := '1'; -- tri-state SDAwhen rd_d =>iscl := '0'; -- set SCL lowisda := '1'; -- tri-state SDAend case;-- generate registersif (nReset = '0') thenSCLo <= '1';SDAo <= '1';elsif (clk'event and clk = '1') thenif (clk_en = '1') thenSCLo <= iscl;SDAo <= isda;end if;end if;end process output_decoder;SCL <= '0' when (SCLo = '0') else 'Z'; -- since SCL is externally pulled-up convert a '1' to a 'Z'(tri-state)SDA <= '0' when (SDAo = '0') else 'Z'; -- since SDA is externally pulled-up convert a '1' to a 'Z'(tri-state)-- SCL <= SCLo;-- SDA <= SDAo;end architecture structural;
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