2014年11月21日 星期五

An implementation of an FPGA to communicate with a 74HC595 Shift Register


源自於 https://gist.github.com/jjcarrier/1692155

8-Bit Shift Register with Output Latches

module FPGA_2_ShiftReg(CLK, BYTE_IN, EN_IN, RDY, RCLK, SRCLK, OE, SER_OUT);
//----------------------------CONTROL SIGNALS-----------------------------------
input CLK;
input [7:0] BYTE_IN; //8-bit input data
input EN_IN; //BYTE_IN ENABLE, indicates the input data is valid
output RDY; //A ready flag indicator, brought low when EN_IN=1 and stays low
//until EN_IN=0 and the data has been shifted out on SER_OUT
//-----------------------PHYSICAL PIN CONNECTIONS-------------------------------
output RCLK; //Register CLK, pushes the FIFO data to the driver outputs
output SRCLK; //Positive Edge Triggered Shift Register CLK
output OE; //Output Enable (Active Low)
output SER_OUT; //The serial data output
//------------------------------------------------------------------------------
//NOTE: Tie SRCLR to VCC since we never need to clear
//reg [7:0] BYTE_IN = 8'hE7;
reg [8:0] shift=0;
//reg EN_IN=0;
reg RCLK=0;
reg SRCLK=0;
reg RDY=1;
wire OE;
//==============================================================================
//--------------------------------PARAMETERS------------------------------------
//==============================================================================
//If we assume CLK=24MHz, then T~=42nS
//If VCC=3.3V, SRCLK at worst case is capable of 5MHz and at best 25MHz
//Lets assume SRCLK=12MHz, T_SCLK~=84nS
//See page 7 of the SN74HC595 datasheet for the parameters below
//------------------------------NUMBER OF BITS----------------------------------
parameter N=2; //This parameter is used on several registers/parameters below
//---------------------PULSE DURATION PARAMETER (PAGE7)-------------------------
//This parameter is used to specify in how many clock cycles of CLK must
//occur prior to setting or unsetting SRCLK/RCLK HI or LO
parameter [N-1:0] pulse_duration = 3; //safety time > 100ns, >=3 CLK cycles
//---------------------SETUP TIME PARAMETER (PAGE7)-----------------------------
//This parameter is used to control how much time is required to setup the
//SER_OUT signal prior to setting SRCLK HI.
//Note there is no required hold duration, once the signal is written to SER,
//and SRCLK has gone HI, the next signal can be immediately setup
parameter [N-1:0] setup_time = 3; //Safety time > 125ns, >=3 CLK cycles
//==============================================================================
//----------------------------ASSIGN THE SER_OUT--------------------------------
//==============================================================================
//The SER_OUT port can be thought of as a wire to the MSB of an 8-bit shift reg
wire SER_OUT;
assign SER_OUT = shift[8]; //shift data out using MSBF
//==============================================================================
//--------------------------CREATE THE SRCLK SIGNAL-----------------------------
//==============================================================================
//Create the SRCLK signal that will be used to clock-in the serial data
reg [N-1:0] clk_cnt=0;
reg [1:0] SRCLK_state=0;
reg SRCLK_toggle=0; //Instructs the process to toggle SRCLK for a period of time
always @(posedge CLK) begin
case(SRCLK_state)
0: begin //Wait for SRCLK_toggle=1
if(SRCLK_toggle==1)begin
SRCLK_state<=SRCLK_state+1;
SRCLK<=0; //Make sure SRCLK is low
clk_cnt<=0;
end
end
1: begin //Wait for the defined setup time, prior to setting SRCLK HI
if(clk_cnt==setup_time-1)begin
SRCLK<=1;
clk_cnt<=0;
SRCLK_state<=SRCLK_state+1;
end else begin
clk_cnt<=clk_cnt+1;
end
end
2: begin //Wait for the defined pulse duration, prior to setting SRCLK LO
if(clk_cnt==pulse_duration-1)begin
SRCLK<=0;
clk_cnt<=0;
SRCLK_state<=SRCLK_state+1;
end else begin
clk_cnt<=clk_cnt+1;
end
end
3: begin //Wait for SRCLK_toggle=0
if(SRCLK_toggle==0) SRCLK_state<=0;
end
endcase
end
//==============================================================================
//--------------------------CREATE THE RCLK SIGNAL------------------------------
//==============================================================================
//Create the RCLK signal that will be used to clock-out the parallel data
reg [N-1:0] clk_cnt2=0;
reg [1:0] RCLK_state=0;
reg RCLK_toggle=0; //Instructs the process to toggle RCLK for a period of time
always @(posedge CLK) begin
case(RCLK_state)
0: begin //Wait for RCLK_toggle=1
if(RCLK_toggle==1)begin
RCLK_state<=RCLK_state+1;
RCLK<=0; //Make sure RCLK is low
clk_cnt2<=0;
end
end
1: begin //Wait for the defined setup time, prior to setting RCLK HI
if(clk_cnt2==setup_time-1)begin
RCLK<=1;
clk_cnt2<=0;
RCLK_state<=RCLK_state+1;
end else begin
clk_cnt2<=clk_cnt2+1;
end
end
2: begin //Wait for the defined pulse duration, prior to setting SRCLK LO
if(clk_cnt2==pulse_duration-1)begin
RCLK<=0;
clk_cnt2<=0;
RCLK_state<=RCLK_state+1;
end else begin
clk_cnt2<=clk_cnt2+1;
end
end
3: begin //Wait for RCLK_toggle=0
if(RCLK_toggle==0) RCLK_state<=0;
end
endcase
end
//==============================================================================
//-------------------CREATE THE FUNCTIONAL SWITCHING LOGIC----------------------
//==============================================================================
reg [1:0] state=0; //Statemachine variable
reg [1:0] substate=0;
reg [2:0] cnt=0;
reg init_done=0;
always @(posedge CLK) begin
case(state)
0: begin //-----------------------------Populate the FPGA's shift register
if(EN_IN==1)begin //Only start the statemachine when input is enabled
shift[7:0]<=BYTE_IN;
//shift[8]<=0;
cnt<=0;
state<=state+1;
RDY<=0;
SRCLK_toggle<=0;
RCLK_toggle<=0;
substate<=0;
end else begin
RDY<=1;
cnt<=0;
SRCLK_toggle<=0;
RCLK_toggle<=0;
state<=0;
substate<=0;
end
end
1: begin //-----------------------------------------Push the bits out MSBF
case(substate)
0: begin //PUSH DATA ON SER
shift[8:1]<=shift[7:0];
shift[0]<=0;
substate<=substate+1;
end
1: begin //PULSE SRCLK
SRCLK_toggle<=1;
substate<=substate+1;
end
2: begin //TURN OFF THE TOGGLE BIT
if(SRCLK==1)begin
SRCLK_toggle<=0;
substate<=substate+1;
end
end
3: begin //WHEN SRCLK GOES LOW, CHECK & UPDATE cnt
if(SRCLK==0)begin
if(cnt==7)begin
//All bits have been shifted
state<=state+1;
cnt<=0;
end else begin
//We have more bits to shift
cnt<=cnt+1;
end
substate<=0;
end
end
endcase
end
2: begin //--------------------------Update & Activate the parallel output
//First Pulse RCLK
//Then indicate init_done
case(substate)
0: begin //PULSE RCLK
RCLK_toggle<=1;
substate<=substate+1;
end
1: begin //TURN OFF THE TOGGLE BIT
if(RCLK==1)begin
RCLK_toggle<=0;
substate<=substate+1;
end
end
2: begin //WHEN RCLK GOES LOW, CHECK & UPDATE cnt
if(RCLK==0)begin
state<=0;
substate<=0;
init_done<=1;
RDY<=1;
end
end
endcase
end
default: begin
state<=0;
substate<=0;
init_done<=0;
RDY<=1;
end
endcase
end
//==============================================================================
//------------------------INITIALIZATION DONE PROCESS---------------------------
//==============================================================================
//This is when the shift register's outputs are switched from HI-Z to LO-Z.
//We will use this as the point in time when we should activate the outputs
//after powerup. At powerup the chip will be in HI-Z state since the data will
//not be valid. Once the user feeds data into this module, and the module
//processes the request, the shift register's output will be enabled
//permenantly. The subsequent data that is fed into this module will be updated
//once all 8-bits are shifted into position. This is done in the logic process
//above.
reg EN_OUT=0;
always @(posedge CLK) begin
if(init_done==1)begin
EN_OUT<=1;
end else begin
EN_OUT<=0;
end
end
assign OE=~EN_OUT; //Invert OE since it is active low
endmodule

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