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[/] [openmsp430/] [trunk/] [fpga/] [actel_m1a3pl_dev_kit/] [rtl/] [verilog/] [openmsp430/] [omsp_dbg_i2c.v] - Rev 211
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//---------------------------------------------------------------------------- // Copyright (C) 2009 , Olivier Girard // // 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. // * Neither the name of the authors nor the names of its contributors // may be used to endorse or promote products derived from this software // without specific prior written permission. // // 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 // //---------------------------------------------------------------------------- // // *File Name: omsp_dbg_i2c.v // // *Module Description: // Debug I2C Slave communication interface // // *Author(s): // - Olivier Girard, olgirard@gmail.com // //---------------------------------------------------------------------------- // $Rev: 103 $ // $LastChangedBy: olivier.girard $ // $LastChangedDate: 2011-03-05 15:44:48 +0100 (Sat, 05 Mar 2011) $ //---------------------------------------------------------------------------- `ifdef OMSP_NO_INCLUDE `else `include "openMSP430_defines.v" `endif module omsp_dbg_i2c ( // OUTPUTs dbg_addr, // Debug register address dbg_din, // Debug register data input dbg_i2c_sda_out, // Debug interface: I2C SDA OUT dbg_rd, // Debug register data read dbg_wr, // Debug register data write // INPUTs dbg_clk, // Debug unit clock dbg_dout, // Debug register data output dbg_i2c_addr, // Debug interface: I2C ADDRESS dbg_i2c_broadcast, // Debug interface: I2C Broadcast Address (for multicore systems) dbg_i2c_scl, // Debug interface: I2C SCL dbg_i2c_sda_in, // Debug interface: I2C SDA IN dbg_rst, // Debug unit reset mem_burst, // Burst on going mem_burst_end, // End TX/RX burst mem_burst_rd, // Start TX burst mem_burst_wr, // Start RX burst mem_bw // Burst byte width ); // OUTPUTs //========= output [5:0] dbg_addr; // Debug register address output [15:0] dbg_din; // Debug register data input output dbg_i2c_sda_out; // Debug interface: I2C SDA OUT output dbg_rd; // Debug register data read output dbg_wr; // Debug register data write // INPUTs //========= input dbg_clk; // Debug unit clock input [15:0] dbg_dout; // Debug register data output input [6:0] dbg_i2c_addr; // Debug interface: I2C ADDRESS input [6:0] dbg_i2c_broadcast; // Debug interface: I2C Broadcast Address (for multicore systems) input dbg_i2c_scl; // Debug interface: I2C SCL input dbg_i2c_sda_in; // Debug interface: I2C SDA IN input dbg_rst; // Debug unit reset input mem_burst; // Burst on going input mem_burst_end; // End TX/RX burst input mem_burst_rd; // Start TX burst input mem_burst_wr; // Start RX burst input mem_bw; // Burst byte width //============================================================================= // 1) I2C RECEIVE LINE SYNCHRONIZTION & FILTERING //============================================================================= // Synchronize SCL/SDA inputs //-------------------------------- wire scl_sync_n; omsp_sync_cell sync_cell_i2c_scl ( .data_out (scl_sync_n), .data_in (~dbg_i2c_scl), .clk (dbg_clk), .rst (dbg_rst) ); wire scl_sync = ~scl_sync_n; wire sda_in_sync_n; omsp_sync_cell sync_cell_i2c_sda ( .data_out (sda_in_sync_n), .data_in (~dbg_i2c_sda_in), .clk (dbg_clk), .rst (dbg_rst) ); wire sda_in_sync = ~sda_in_sync_n; // SCL/SDA input buffers //-------------------------------- reg [1:0] scl_buf; always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) scl_buf <= 2'h3; else scl_buf <= {scl_buf[0], scl_sync}; reg [1:0] sda_in_buf; always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) sda_in_buf <= 2'h3; else sda_in_buf <= {sda_in_buf[0], sda_in_sync}; // SCL/SDA Majority decision //------------------------------ wire scl = (scl_sync & scl_buf[0]) | (scl_sync & scl_buf[1]) | (scl_buf[0] & scl_buf[1]); wire sda_in = (sda_in_sync & sda_in_buf[0]) | (sda_in_sync & sda_in_buf[1]) | (sda_in_buf[0] & sda_in_buf[1]); // SCL/SDA Edge detection //------------------------------ // SDA Edge detection reg sda_in_dly; always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) sda_in_dly <= 1'b1; else sda_in_dly <= sda_in; wire sda_in_fe = sda_in_dly & ~sda_in; wire sda_in_re = ~sda_in_dly & sda_in; wire sda_in_edge = sda_in_dly ^ sda_in; // SCL Edge detection reg scl_dly; always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) scl_dly <= 1'b1; else scl_dly <= scl; wire scl_fe = scl_dly & ~scl; wire scl_re = ~scl_dly & scl; wire scl_edge = scl_dly ^ scl; // Delayed SCL Rising-Edge for SDA data sampling reg [1:0] scl_re_dly; always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) scl_re_dly <= 2'b00; else scl_re_dly <= {scl_re_dly[0], scl_re}; wire scl_sample = scl_re_dly[1]; //============================================================================= // 2) I2C START & STOP CONDITION DETECTION //============================================================================= //----------------- // Start condition //----------------- wire start_detect = sda_in_fe & scl; //----------------- // Stop condition //----------------- wire stop_detect = sda_in_re & scl; //----------------- // I2C Slave Active //----------------- // The I2C logic will be activated whenever a start condition // is detected and will be disactivated if the slave address // doesn't match or if a stop condition is detected. wire i2c_addr_not_valid; reg i2c_active_seq; always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) i2c_active_seq <= 1'b0; else if (start_detect) i2c_active_seq <= 1'b1; else if (stop_detect || i2c_addr_not_valid) i2c_active_seq <= 1'b0; wire i2c_active = i2c_active_seq & ~stop_detect; wire i2c_init = ~i2c_active | start_detect; //============================================================================= // 3) I2C STATE MACHINE //============================================================================= // State register/wires reg [2:0] i2c_state; reg [2:0] i2c_state_nxt; // Utility signals reg [8:0] shift_buf; wire shift_rx_done; wire shift_tx_done; reg dbg_rd; // State machine definition parameter RX_ADDR = 3'h0; parameter RX_ADDR_ACK = 3'h1; parameter RX_DATA = 3'h2; parameter RX_DATA_ACK = 3'h3; parameter TX_DATA = 3'h4; parameter TX_DATA_ACK = 3'h5; // State transition always @(i2c_state or i2c_init or shift_rx_done or i2c_addr_not_valid or shift_tx_done or scl_fe or shift_buf or sda_in) case (i2c_state) RX_ADDR : i2c_state_nxt = i2c_init ? RX_ADDR : ~shift_rx_done ? RX_ADDR : i2c_addr_not_valid ? RX_ADDR : RX_ADDR_ACK; RX_ADDR_ACK : i2c_state_nxt = i2c_init ? RX_ADDR : ~scl_fe ? RX_ADDR_ACK : shift_buf[0] ? TX_DATA : RX_DATA; RX_DATA : i2c_state_nxt = i2c_init ? RX_ADDR : ~shift_rx_done ? RX_DATA : RX_DATA_ACK; RX_DATA_ACK : i2c_state_nxt = i2c_init ? RX_ADDR : ~scl_fe ? RX_DATA_ACK : RX_DATA; TX_DATA : i2c_state_nxt = i2c_init ? RX_ADDR : ~shift_tx_done ? TX_DATA : TX_DATA_ACK; TX_DATA_ACK : i2c_state_nxt = i2c_init ? RX_ADDR : ~scl_fe ? TX_DATA_ACK : ~sda_in ? TX_DATA : RX_ADDR; // pragma coverage off default : i2c_state_nxt = RX_ADDR; // pragma coverage on endcase // State machine always @(posedge dbg_clk or posedge dbg_rst) if (dbg_rst) i2c_state <= RX_ADDR; else i2c_state <= i2c_state_nxt; //============================================================================= // 4) I2C SHIFT REGISTER (FOR RECEIVING & TRANSMITING) //============================================================================= wire shift_rx_en = ((i2c_state==RX_ADDR) | (i2c_state ==RX_DATA) | (i2c_state ==RX_DATA_ACK)); wire shift_tx_en = (i2c_state ==TX_DATA) | (i2c_state ==TX_DATA_ACK); wire shift_tx_en_pre = (i2c_state_nxt==TX_DATA) | (i2c_state_nxt==TX_DATA_ACK); assign shift_rx_done = shift_rx_en & scl_fe & shift_buf[8]; assign shift_tx_done = shift_tx_en & scl_fe & (shift_buf==9'h100); wire shift_buf_rx_init = i2c_init | ((i2c_state==RX_ADDR_ACK) & scl_fe & ~shift_buf[0]) | ((i2c_state==RX_DATA_ACK) & scl_fe); wire shift_buf_rx_en = shift_rx_en & scl_sample; wire shift_buf_tx_init = ((i2c_state==RX_ADDR_ACK) & scl_re & shift_buf[0]) | ((i2c_state==TX_DATA_ACK) & scl_re); wire shift_buf_tx_en = shift_tx_en_pre & scl_fe & (shift_buf!=9'h100); wire [7:0] shift_tx_val; wire [8:0] shift_buf_nxt = shift_buf_rx_init ? 9'h001 : // RX Init shift_buf_tx_init ? {shift_tx_val, 1'b1} : // TX Init shift_buf_rx_en ? {shift_buf[7:0], sda_in} : // RX Shift shift_buf_tx_en ? {shift_buf[7:0], 1'b0} : // TX Shift shift_buf[8:0]; // Hold always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) shift_buf <= 9'h001; else shift_buf <= shift_buf_nxt; // Detect when the received I2C device address is not valid assign i2c_addr_not_valid = (i2c_state == RX_ADDR) && shift_rx_done && ( `ifdef DBG_I2C_BROADCAST (shift_buf[7:1] != dbg_i2c_broadcast[6:0]) && `endif (shift_buf[7:1] != dbg_i2c_addr[6:0])); `ifdef DBG_I2C_BROADCAST `else wire [6:0] UNUSED_dbg_i2c_broadcast = dbg_i2c_broadcast; `endif // Utility signals wire shift_rx_data_done = shift_rx_done & (i2c_state==RX_DATA); wire shift_tx_data_done = shift_tx_done; //============================================================================= // 5) I2C TRANSMIT BUFFER //============================================================================= reg dbg_i2c_sda_out; always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) dbg_i2c_sda_out <= 1'b1; else if (scl_fe) dbg_i2c_sda_out <= ~((i2c_state_nxt==RX_ADDR_ACK) || (i2c_state_nxt==RX_DATA_ACK) || (shift_buf_tx_en & ~shift_buf[8])); //============================================================================= // 6) DEBUG INTERFACE STATE MACHINE //============================================================================= // State register/wires reg [2:0] dbg_state; reg [2:0] dbg_state_nxt; // Utility signals reg dbg_bw; // State machine definition parameter RX_CMD = 3'h0; parameter RX_BYTE_LO = 3'h1; parameter RX_BYTE_HI = 3'h2; parameter TX_BYTE_LO = 3'h3; parameter TX_BYTE_HI = 3'h4; // State transition always @(dbg_state or shift_rx_data_done or shift_tx_data_done or shift_buf or dbg_bw or mem_burst_wr or mem_burst_rd or mem_burst or mem_burst_end or mem_bw) case (dbg_state) RX_CMD : dbg_state_nxt = mem_burst_wr ? RX_BYTE_LO : mem_burst_rd ? TX_BYTE_LO : ~shift_rx_data_done ? RX_CMD : shift_buf[7] ? RX_BYTE_LO : TX_BYTE_LO; RX_BYTE_LO : dbg_state_nxt = (mem_burst & mem_burst_end) ? RX_CMD : ~shift_rx_data_done ? RX_BYTE_LO : (mem_burst & ~mem_burst_end) ? (mem_bw ? RX_BYTE_LO : RX_BYTE_HI) : dbg_bw ? RX_CMD : RX_BYTE_HI; RX_BYTE_HI : dbg_state_nxt = ~shift_rx_data_done ? RX_BYTE_HI : (mem_burst & ~mem_burst_end) ? RX_BYTE_LO : RX_CMD; TX_BYTE_LO : dbg_state_nxt = ~shift_tx_data_done ? TX_BYTE_LO : ( mem_burst & mem_bw) ? TX_BYTE_LO : ( mem_burst & ~mem_bw) ? TX_BYTE_HI : ~dbg_bw ? TX_BYTE_HI : RX_CMD; TX_BYTE_HI : dbg_state_nxt = ~shift_tx_data_done ? TX_BYTE_HI : mem_burst ? TX_BYTE_LO : RX_CMD; // pragma coverage off default : dbg_state_nxt = RX_CMD; // pragma coverage on endcase // State machine always @(posedge dbg_clk or posedge dbg_rst) if (dbg_rst) dbg_state <= RX_CMD; else dbg_state <= dbg_state_nxt; // Utility signals wire cmd_valid = (dbg_state==RX_CMD) & shift_rx_data_done; wire rx_lo_valid = (dbg_state==RX_BYTE_LO) & shift_rx_data_done; wire rx_hi_valid = (dbg_state==RX_BYTE_HI) & shift_rx_data_done; //============================================================================= // 7) REGISTER READ/WRITE ACCESS //============================================================================= parameter MEM_DATA = 6'h06; // Debug register address & bit width reg [5:0] dbg_addr; always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) begin dbg_bw <= 1'b0; dbg_addr <= 6'h00; end else if (cmd_valid) begin dbg_bw <= shift_buf[6]; dbg_addr <= shift_buf[5:0]; end else if (mem_burst) begin dbg_bw <= mem_bw; dbg_addr <= MEM_DATA; end // Debug register data input reg [7:0] dbg_din_lo; always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) dbg_din_lo <= 8'h00; else if (rx_lo_valid) dbg_din_lo <= shift_buf[7:0]; reg [7:0] dbg_din_hi; always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) dbg_din_hi <= 8'h00; else if (rx_lo_valid) dbg_din_hi <= 8'h00; else if (rx_hi_valid) dbg_din_hi <= shift_buf[7:0]; assign dbg_din = {dbg_din_hi, dbg_din_lo}; // Debug register data write command reg dbg_wr; always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) dbg_wr <= 1'b0; else dbg_wr <= (mem_burst & mem_bw) ? rx_lo_valid : (mem_burst & ~mem_bw) ? rx_hi_valid : dbg_bw ? rx_lo_valid : rx_hi_valid; // Debug register data read command always @ (posedge dbg_clk or posedge dbg_rst) if (dbg_rst) dbg_rd <= 1'b0; else dbg_rd <= (mem_burst & mem_bw) ? (shift_tx_data_done & (dbg_state==TX_BYTE_LO)) : (mem_burst & ~mem_bw) ? (shift_tx_data_done & (dbg_state==TX_BYTE_HI)) : cmd_valid ? ~shift_buf[7] : 1'b0; // Debug register data read value assign shift_tx_val = (dbg_state==TX_BYTE_HI) ? dbg_dout[15:8] : dbg_dout[7:0]; endmodule `ifdef OMSP_NO_INCLUDE `else `include "openMSP430_undefines.v" `endif
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