From 2ab8de5bcae8fd8f529a49d03dc69dc1e3377260 Mon Sep 17 00:00:00 2001 From: Paul Selkirk Date: Tue, 18 Nov 2014 15:29:31 -0500 Subject: i2c_device_addr as output --- src/rtl/coretest_hashes.v | 2 - src/rtl/i2c_core.v | 581 ---------------------------------------------- 2 files changed, 583 deletions(-) delete mode 100644 src/rtl/i2c_core.v (limited to 'src/rtl') diff --git a/src/rtl/coretest_hashes.v b/src/rtl/coretest_hashes.v index 567d4f7..9067674 100644 --- a/src/rtl/coretest_hashes.v +++ b/src/rtl/coretest_hashes.v @@ -115,8 +115,6 @@ module coretest_hashes( .SCL(SCL), .SDA(SDA), .SDA_pd(SDA_pd), - .i2c_addr_low(I2C_SHA1_ADDR), - .i2c_addr_high(I2C_SHA512_ADDR), .i2c_device_addr(i2c_device_addr), .rxd_syn(i2c_rxd_syn), diff --git a/src/rtl/i2c_core.v b/src/rtl/i2c_core.v deleted file mode 100644 index cbf76c6..0000000 --- a/src/rtl/i2c_core.v +++ /dev/null @@ -1,581 +0,0 @@ -////////////////////////////////////////////////////////////////////////////// -// Copyright (c) 2011, Andrew "bunnie" Huang -// All rights reserved. -// -// Redistribution and use in source and binary forms, with or without modification, -// are permitted provided that the following conditions are met: -// -// * Redistributions of source code must retain the above copyright notice, -// this list of conditions and the following disclaimer. -// * Redistributions in binary form must reproduce the above copyright notice, -// this list of conditions and the following disclaimer in the documentation and/or -// other materials provided with the distribution. -// -// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY -// EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES -// OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT -// SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, -// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT -// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR -// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, -// WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) -// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE -// POSSIBILITY OF SUCH DAMAGE. -// -////////////////////////////////////////////////////////////////////////////// -// A simple I2C slave implementation. Oversampled for robustness. -// The slave is extended into the snoop & surpress version for the DDC bus; -// this is just a starting point for basic testing and also simple comms -// with the CPU. -// -// i2c slave module requires the top level module to implement the IOBs -// This is just to keep the tri-state easy to implemen across the hierarchy -// -// The code required on the top level is: -// IOBUF #(.DRIVE(12), .SLEW("SLOW")) IOBUF_sda (.IO(SDA), .I(1'b0), .T(!SDA_pd)); -// -/////////// -`timescale 1 ns / 1 ps - -module i2c_core ( - input wire clk, - input wire reset, - - // External data interface - input wire SCL, - input wire SDA, - output reg SDA_pd, - input wire [6:0] i2c_addr_low, - input wire [6:0] i2c_addr_high, - output wire [6:0] i2c_device_addr, - - // Internal receive interface. - output wire rxd_syn, - output [7 : 0] rxd_data, - input wire rxd_ack, - - // Internal transmit interface. - input wire txd_syn, - input wire [7 : 0] txd_data, - output wire txd_ack - ); - - /////// I2C physical layer components - /// SDA is stable when SCL is high. - /// If SDA moves while SCL is high, this is considered a start or stop condition. - /// - /// Otherwise, SDA can move around when SCL is low (this is where we suppress bits or - /// overdrive as needed). SDA is a wired-AND bus, so you only "drive" zero. - /// - /// In an oversampled implementation, a rising and falling edge de-glitcher is needed - /// for SCL and SDA. - /// - - // rise fall time cycles computation: - // At 400kHz operation, 2.5us is a cycle. "chatter" from transition should be about - // 5% of total cycle time max (just rule of thumb), so 0.125us should be the equiv - // number of cycles. - // For the demo board, a 25 MHz clock is provided, and 0.125us ~ 4 cycles - // At 100kHz operation, 10us is a cycle, so 0.5us ~ 12 cycles - parameter TRF_CYCLES = 5'd4; // number of cycles for rise/fall time - - //////////////// - ///// protocol-level state machine - //////////////// - parameter I2C_START = 16'b1 << 0; // should only pass through this state for one cycle - parameter I2C_RESTART = 16'b1 << 1; - parameter I2C_DADDR = 16'b1 << 2; - parameter I2C_ACK_DADDR = 16'b1 << 3; - parameter I2C_WR_DATA = 16'b1 << 4; - parameter I2C_ACK_WR = 16'b1 << 5; - parameter I2C_END_WR = 16'b1 << 6; - parameter I2C_RD_DATA = 16'b1 << 7; - parameter I2C_ACK_RD = 16'b1 << 8; - parameter I2C_END_RD = 16'b1 << 9; - parameter I2C_END_RD2 = 16'b1 << 10; - parameter I2C_WAITSTOP = 16'b1 << 11; - parameter I2C_RXD_SYN = 16'b1 << 12; - parameter I2C_RXD_ACK = 16'b1 << 13; - parameter I2C_TXD_SYN = 16'b1 << 14; - parameter I2C_TXD_ACK = 16'b1 << 15; - - parameter I2C_nSTATES = 16; - - reg [(I2C_nSTATES-1):0] I2C_cstate = {{(I2C_nSTATES-1){1'b0}}, 1'b1}; //current and next states - reg [(I2C_nSTATES-1):0] I2C_nstate; - -//`define SIMULATION -`ifdef SIMULATION - // synthesis translate_off - reg [8*20:1] I2C_state_ascii = "I2C_START "; - always @(I2C_cstate) begin - if (I2C_cstate == I2C_START) I2C_state_ascii <= "I2C_START "; - else if (I2C_cstate == I2C_RESTART) I2C_state_ascii <= "I2C_RESTART "; - else if (I2C_cstate == I2C_DADDR) I2C_state_ascii <= "I2C_DADDR "; - else if (I2C_cstate == I2C_ACK_DADDR) I2C_state_ascii <= "I2C_ACK_DADDR "; - else if (I2C_cstate == I2C_WR_DATA) I2C_state_ascii <= "I2C_WR_DATA "; - else if (I2C_cstate == I2C_ACK_WR) I2C_state_ascii <= "I2C_ACK_WR "; - else if (I2C_cstate == I2C_END_WR) I2C_state_ascii <= "I2C_END_WR "; - else if (I2C_cstate == I2C_RD_DATA) I2C_state_ascii <= "I2C_RD_DATA "; - else if (I2C_cstate == I2C_ACK_RD) I2C_state_ascii <= "I2C_ACK_RD "; - else if (I2C_cstate == I2C_END_RD) I2C_state_ascii <= "I2C_END_RD "; - else if (I2C_cstate == I2C_END_RD2) I2C_state_ascii <= "I2C_END_RD2 "; - else if (I2C_cstate == I2C_WAITSTOP) I2C_state_ascii <= "I2C_WAITSTOP "; - else if (I2C_cstate == I2C_RXD_SYN) I2C_state_ascii <= "I2C_RXD_SYN "; - else if (I2C_cstate == I2C_RXD_ACK) I2C_state_ascii <= "I2C_RXD_ACK "; - else if (I2C_cstate == I2C_TXD_SYN) I2C_state_ascii <= "I2C_TXD_SYN "; - else if (I2C_cstate == I2C_TXD_ACK) I2C_state_ascii <= "I2C_TXD_ACK "; - else I2C_state_ascii <= "WTF "; - end - // synthesis translate_on -`endif - - reg [3:0] I2C_bitcnt; - reg [7:0] I2C_daddr; - reg [7:0] I2C_wdata; - reg [7:0] I2C_rdata; - - reg rxd_syn_reg; - reg txd_ack_reg; - - assign rxd_data = I2C_wdata; - assign rxd_syn = rxd_syn_reg; - assign txd_ack = txd_ack_reg; - - assign i2c_device_addr = I2C_daddr[7:1]; - - - ////////// code begins here - always @ (posedge clk) begin - if (reset || ((SCL_cstate == SCL_HIGH) && (SDA_cstate == SDA_RISE))) // stop condition always resets - I2C_cstate <= I2C_START; - else - I2C_cstate <= I2C_nstate; - end - - always @ (*) begin - case (I2C_cstate) //synthesis parallel_case full_case - I2C_START: begin // wait for the start condition - I2C_nstate = ((SDA_cstate == SDA_FALL) && (SCL_cstate == SCL_HIGH)) ? I2C_DADDR : I2C_START; - end - I2C_RESTART: begin // repeated start moves immediately to DADDR - I2C_nstate = I2C_DADDR; - end - - // device address branch - I2C_DADDR: begin // 8 bits to get the address - I2C_nstate = ((I2C_bitcnt > 4'h7) && (SCL_cstate == SCL_FALL)) ? I2C_ACK_DADDR : I2C_DADDR; - end - I2C_ACK_DADDR: begin // depending upon W/R bit state, go to one of two branches - I2C_nstate = (SCL_cstate == SCL_FALL) ? - ((I2C_daddr[7:1] >= i2c_addr_low) && - (I2C_daddr[7:1] <= i2c_addr_high)) ? - (I2C_daddr[0] == 1'b0 ? I2C_WR_DATA : I2C_TXD_SYN) : - I2C_WAITSTOP : // !I2C_daddr match - I2C_ACK_DADDR; // !SCL_FALL - end - - // write branch - I2C_WR_DATA: begin // 8 bits to get the write data - I2C_nstate = ((SDA_cstate == SDA_FALL) && (SCL_cstate == SCL_HIGH)) ? I2C_RESTART : // repeated start - ((I2C_bitcnt > 4'h7) && (SCL_cstate == SCL_FALL)) ? I2C_RXD_SYN : I2C_WR_DATA; - end - I2C_RXD_SYN: begin // put data on the coretest bus - I2C_nstate = I2C_RXD_ACK; - end - I2C_RXD_ACK: begin // wait for coretest ack - I2C_nstate = rxd_ack ? I2C_ACK_WR : I2C_RXD_ACK; - end - I2C_ACK_WR: begin // trigger the ack response (pull SDA low until next falling edge) - // and stay in this state until the next falling edge of SCL - I2C_nstate = (SCL_cstate == SCL_FALL) ? I2C_END_WR : I2C_ACK_WR; - end - I2C_END_WR: begin // one-cycle state to update address+1, reset SDA pulldown - I2C_nstate = I2C_WR_DATA; // SCL is now low - end - - // read branch - I2C_TXD_SYN: begin // get data from the coretest bus - // if data isn't available (txd_syn isn't asserted) by the time we - // get to this state, it probably never will be, so skip it - I2C_nstate = txd_syn ? I2C_TXD_ACK : I2C_RD_DATA; - end - I2C_TXD_ACK: begin // send coretest ack - // hold ack high until syn is lowered - I2C_nstate = txd_syn ? I2C_TXD_ACK : I2C_RD_DATA; - end - I2C_RD_DATA: begin // 8 bits to get the read data - I2C_nstate = ((SDA_cstate == SDA_FALL) && (SCL_cstate == SCL_HIGH)) ? I2C_RESTART : // repeated start - ((I2C_bitcnt > 4'h7) && (SCL_cstate == SCL_FALL)) ? I2C_ACK_RD : I2C_RD_DATA; - end - I2C_ACK_RD: begin // wait for an (n)ack response - // need to sample (n)ack on a rising edge - I2C_nstate = (SCL_cstate == SCL_RISE) ? I2C_END_RD : I2C_ACK_RD; - end - I2C_END_RD: begin // if nack, just go to start state (don't explicitly check stop event) - // single cycle state for adr+1 update - I2C_nstate = (SDA_cstate == SDA_LOW) ? I2C_END_RD2 : I2C_START; - end - I2C_END_RD2: begin // before entering I2C_RD_DATA, we need to have seen a falling edge. - I2C_nstate = (SCL_cstate == SCL_FALL) ? I2C_RD_DATA : I2C_END_RD2; - end - - // we're not the addressed device, so we just idle until we see a stop - I2C_WAITSTOP: begin - I2C_nstate = (((SCL_cstate == SCL_HIGH) && (SDA_cstate == SDA_RISE))) ? // stop - I2C_START : - (((SCL_cstate == SCL_HIGH) && (SDA_cstate == SDA_FALL))) ? // or start - I2C_RESTART : - I2C_WAITSTOP; - end - endcase // case (cstate) - end - - always @ (posedge clk) begin - if( reset ) begin - I2C_bitcnt <= 4'b0; - I2C_daddr <= 8'b0; - I2C_wdata <= 8'b0; - SDA_pd <= 1'b0; - I2C_rdata <= 8'b0; - end else begin - case (I2C_cstate) // synthesis parallel_case full_case - I2C_START: begin // everything in reset - I2C_bitcnt <= 4'b0; - I2C_daddr <= 8'b0; - I2C_wdata <= 8'b0; - I2C_rdata <= 8'b0; - SDA_pd <= 1'b0; - end - - I2C_RESTART: begin - I2C_bitcnt <= 4'b0; - I2C_daddr <= 8'b0; - I2C_wdata <= 8'b0; - I2C_rdata <= 8'b0; - SDA_pd <= 1'b0; - end - - // get my i2c device address (am I being talked to?) - I2C_DADDR: begin // shift in the address on rising edges of clock - if( SCL_cstate == SCL_RISE ) begin - I2C_bitcnt <= I2C_bitcnt + 4'b1; - I2C_daddr[7] <= I2C_daddr[6]; - I2C_daddr[6] <= I2C_daddr[5]; - I2C_daddr[5] <= I2C_daddr[4]; - I2C_daddr[4] <= I2C_daddr[3]; - I2C_daddr[3] <= I2C_daddr[2]; - I2C_daddr[2] <= I2C_daddr[1]; - I2C_daddr[1] <= I2C_daddr[0]; - I2C_daddr[0] <= (SDA_cstate == SDA_HIGH) ? 1'b1 : 1'b0; - end else begin // we're oversampled so we need a hold-state gutter - I2C_bitcnt <= I2C_bitcnt; - I2C_daddr <= I2C_daddr; - end // else: !if( SCL_cstate == SCL_RISE ) - SDA_pd <= 1'b0; - I2C_wdata <= 8'b0; - I2C_rdata <= 8'b0; - end // case: I2C_DADDR - I2C_ACK_DADDR: begin - SDA_pd <= 1'b1; // active pull down ACK - I2C_daddr <= I2C_daddr; - I2C_bitcnt <= 4'b0; - I2C_wdata <= 8'b0; - I2C_rdata <= 8'b0; - end - - // write branch - I2C_WR_DATA: begin // shift in data on rising edges of clock - if( SCL_cstate == SCL_RISE ) begin - I2C_bitcnt <= I2C_bitcnt + 4'b1; - I2C_wdata[7] <= I2C_wdata[6]; - I2C_wdata[6] <= I2C_wdata[5]; - I2C_wdata[5] <= I2C_wdata[4]; - I2C_wdata[4] <= I2C_wdata[3]; - I2C_wdata[3] <= I2C_wdata[2]; - I2C_wdata[2] <= I2C_wdata[1]; - I2C_wdata[1] <= I2C_wdata[0]; - I2C_wdata[0] <= (SDA_cstate == SDA_HIGH) ? 1'b1 : 1'b0; - end else begin - I2C_bitcnt <= I2C_bitcnt; // hold state gutter - I2C_wdata <= I2C_wdata; - end // else: !if( SCL_cstate == SCL_RISE ) - SDA_pd <= 1'b0; - I2C_daddr <= I2C_daddr; - I2C_rdata <= I2C_rdata; - end // case: I2C_WR_DATA - I2C_RXD_SYN: begin // put data on the coretest bus and raise syn - rxd_syn_reg <= 1; - end - I2C_RXD_ACK: begin // wait for coretest ack - if (rxd_ack) - rxd_syn_reg <= 0; - end - I2C_ACK_WR: begin - SDA_pd <= 1'b1; // active pull down ACK - I2C_daddr <= I2C_daddr; - I2C_bitcnt <= 4'b0; - I2C_wdata <= I2C_wdata; - I2C_rdata <= I2C_rdata; - end - I2C_END_WR: begin - SDA_pd <= 1'b0; // let SDA rise (host may look for this to know ack is done - I2C_bitcnt <= 4'b0; - I2C_wdata <= 8'b0; - I2C_rdata <= I2C_rdata; - I2C_daddr <= I2C_daddr; - end - - // read branch - I2C_TXD_SYN: begin // get data from the coretest bus - if (txd_syn) begin - I2C_rdata <= txd_data; - txd_ack_reg <= 1; - end - end - I2C_TXD_ACK: begin // send coretest ack - if (!txd_syn) - txd_ack_reg <= 0; - end - I2C_RD_DATA: begin // shift out data on falling edges of clock - SDA_pd <= I2C_rdata[7] ? 1'b0 : 1'b1; - if( SCL_cstate == SCL_RISE ) begin - I2C_bitcnt <= I2C_bitcnt + 4'b1; - end else begin - I2C_bitcnt <= I2C_bitcnt; // hold state gutter - end - - if( SCL_cstate == SCL_FALL ) begin - I2C_rdata[7] <= I2C_rdata[6]; - I2C_rdata[6] <= I2C_rdata[5]; - I2C_rdata[5] <= I2C_rdata[4]; - I2C_rdata[4] <= I2C_rdata[3]; - I2C_rdata[3] <= I2C_rdata[2]; - I2C_rdata[2] <= I2C_rdata[1]; - I2C_rdata[1] <= I2C_rdata[0]; - I2C_rdata[0] <= 1'b0; - end else begin - I2C_rdata <= I2C_rdata; - end // else: !if( SCL_cstate == SCL_RISE ) - I2C_daddr <= I2C_daddr; - I2C_wdata <= I2C_wdata; - end // case: I2C_RD_DATA - I2C_ACK_RD: begin - SDA_pd <= 1'b0; // in ack state don't pull down, we are listening to host - I2C_daddr <= I2C_daddr; - I2C_bitcnt <= 4'b0; - I2C_rdata <= I2C_rdata; - I2C_wdata <= I2C_wdata; - end - I2C_END_RD: begin - SDA_pd <= 1'b0; // let SDA rise (host may look for this to know ack is done - I2C_daddr <= I2C_daddr; - I2C_bitcnt <= 4'b0; - I2C_rdata <= I2C_rdata; - I2C_wdata <= I2C_wdata; - end - I2C_END_RD2: begin - SDA_pd <= 1'b0; - I2C_daddr <= 8'b0; - I2C_bitcnt <= 4'b0; - I2C_rdata <= I2C_rdata; - I2C_wdata <= I2C_wdata; - end - - I2C_WAITSTOP: begin - SDA_pd <= 1'b0; - I2C_daddr <= 8'b0; - I2C_bitcnt <= 4'b0; - I2C_rdata <= I2C_rdata; - I2C_wdata <= I2C_wdata; - end - endcase // case (cstate) - end // else: !if( reset ) - end // always @ (posedge clk or posedge reset) - - - /////////////////////////////////////////////////////////////// - /////////// low level state machines ////////////////////////// - /////////////////////////////////////////////////////////////// - - - //////////////// - ///// SCL low-level sampling state machine - //////////////// - parameter SCL_HIGH = 4'b1 << 0; // should only pass through this state for one cycle - parameter SCL_FALL = 4'b1 << 1; - parameter SCL_LOW = 4'b1 << 2; - parameter SCL_RISE = 4'b1 << 3; - parameter SCL_nSTATES = 4; - - reg [(SCL_nSTATES-1):0] SCL_cstate = {{(SCL_nSTATES-1){1'b0}}, 1'b1}; //current and next states - reg [(SCL_nSTATES-1):0] SCL_nstate; - -//`define SIMULATION -`ifdef SIMULATION - // synthesis translate_off - reg [8*20:1] SCL_state_ascii = "SCL_HIGH "; - - always @(SCL_cstate) begin - if (SCL_cstate == SCL_HIGH) SCL_state_ascii <= "SCL_HIGH "; - else if (SCL_cstate == SCL_FALL) SCL_state_ascii <= "SCL_FALL "; - else if (SCL_cstate == SCL_LOW ) SCL_state_ascii <= "SCL_LOW "; - else if (SCL_cstate == SCL_RISE) SCL_state_ascii <= "SCL_RISE "; - else SCL_state_ascii <= "WTF "; - end - // synthesis translate_on -`endif - - reg [4:0] SCL_rfcnt; - reg SCL_s, SCL_sync; - reg SDA_s, SDA_sync; - - always @ (posedge clk) begin - if (reset) - SCL_cstate <= SCL_HIGH; // always start here even if it's wrong -- easier to test - else - SCL_cstate <= SCL_nstate; - end - - always @ (*) begin - case (SCL_cstate) //synthesis parallel_case full_case - SCL_HIGH: begin - SCL_nstate = ((SCL_rfcnt > TRF_CYCLES) && (SCL_sync == 1'b0)) ? SCL_FALL : SCL_HIGH; - end - SCL_FALL: begin - SCL_nstate = SCL_LOW; - end - SCL_LOW: begin - SCL_nstate = ((SCL_rfcnt > TRF_CYCLES) && (SCL_sync == 1'b1)) ? SCL_RISE : SCL_LOW; - end - SCL_RISE: begin - SCL_nstate = SCL_HIGH; - end - endcase // case (cstate) - end // always @ (*) - - always @ (posedge clk) begin - if( reset ) begin - SCL_rfcnt <= 5'b0; - end else begin - case (SCL_cstate) // synthesis parallel_case full_case - SCL_HIGH: begin - if( SCL_sync == 1'b1 ) begin - SCL_rfcnt <= 5'b0; - end else begin - SCL_rfcnt <= SCL_rfcnt + 5'b1; - end - end - SCL_FALL: begin - SCL_rfcnt <= 5'b0; - end - SCL_LOW: begin - if( SCL_sync == 1'b0 ) begin - SCL_rfcnt <= 5'b0; - end else begin - SCL_rfcnt <= SCL_rfcnt + 5'b1; - end - end - SCL_RISE: begin - SCL_rfcnt <= 5'b0; - end - endcase // case (cstate) - end // else: !if( reset ) - end // always @ (posedge clk or posedge reset) - - - //////////////// - ///// SDA low-level sampling state machine - //////////////// - parameter SDA_HIGH = 4'b1 << 0; // should only pass through this state for one cycle - parameter SDA_FALL = 4'b1 << 1; - parameter SDA_LOW = 4'b1 << 2; - parameter SDA_RISE = 4'b1 << 3; - parameter SDA_nSTATES = 4; - - reg [(SDA_nSTATES-1):0] SDA_cstate = {{(SDA_nSTATES-1){1'b0}}, 1'b1}; //current and next states - reg [(SDA_nSTATES-1):0] SDA_nstate; - -//`define SIMULATION -`ifdef SIMULATION - // synthesis translate_off - reg [8*20:1] SDA_state_ascii = "SDA_HIGH "; - - always @(SDA_cstate) begin - if (SDA_cstate == SDA_HIGH) SDA_state_ascii <= "SDA_HIGH "; - else if (SDA_cstate == SDA_FALL) SDA_state_ascii <= "SDA_FALL "; - else if (SDA_cstate == SDA_LOW ) SDA_state_ascii <= "SDA_LOW "; - else if (SDA_cstate == SDA_RISE) SDA_state_ascii <= "SDA_RISE "; - else SDA_state_ascii <= "WTF "; - end - // synthesis translate_on -`endif - - reg [4:0] SDA_rfcnt; - - always @ (posedge clk) begin - if (reset) - SDA_cstate <= SDA_HIGH; // always start here even if it's wrong -- easier to test - else - SDA_cstate <= SDA_nstate; - end - - always @ (*) begin - case (SDA_cstate) //synthesis parallel_case full_case - SDA_HIGH: begin - SDA_nstate = ((SDA_rfcnt > TRF_CYCLES) && (SDA_sync == 1'b0)) ? SDA_FALL : SDA_HIGH; - end - SDA_FALL: begin - SDA_nstate = SDA_LOW; - end - SDA_LOW: begin - SDA_nstate = ((SDA_rfcnt > TRF_CYCLES) && (SDA_sync == 1'b1)) ? SDA_RISE : SDA_LOW; - end - SDA_RISE: begin - SDA_nstate = SDA_HIGH; - end - endcase // case (cstate) - end // always @ (*) - - always @ (posedge clk) begin - if( reset ) begin - SDA_rfcnt <= 5'b0; - end else begin - case (SDA_cstate) // synthesis parallel_case full_case - SDA_HIGH: begin - if( SDA_sync == 1'b1 ) begin - SDA_rfcnt <= 5'b0; - end else begin - SDA_rfcnt <= SDA_rfcnt + 5'b1; - end - end - SDA_FALL: begin - SDA_rfcnt <= 5'b0; - end - SDA_LOW: begin - if( SDA_sync == 1'b0 ) begin - SDA_rfcnt <= 5'b0; - end else begin - SDA_rfcnt <= SDA_rfcnt + 5'b1; - end - end - SDA_RISE: begin - SDA_rfcnt <= 5'b0; - end - endcase // case (cstate) - end // else: !if( reset ) - end // always @ (posedge clk or posedge reset) - - - - ///////////////////// - /////// synchronizers - ///////////////////// - always @ (posedge clk) begin - SCL_s <= SCL; - SCL_sync <= SCL_s; - SDA_s <= SDA; - SDA_sync <= SDA_s; - end // always @ (posedge clk or posedge reset) - -endmodule // i2c_slave -- cgit v1.2.3