verilog/rtl/FPU/FPU_decode.v - third_party/shuttle/sky130/mpw-006/slot-029 - Git at Google

 module FPU_decode #(parameter FPLEN = 16)
    (
    input 		clk,
    input 		rst_l,
    input [31:0] 	instr,
    input 		fpu_active,
    input 		fpu_complete,
    input [FPLEN-1:0]fpu_result_1,
    output [2:0] 	scalar_control,
    output [4:0] 	rs1_address,
    output [4:0] 	rs2_address,
    output [4:0] 	rd_address,
    output 	illegal_instr,
    output [23:0]          sfpu_op,
    output [2:0]           fpu_rnd,
    output [2:0]           fpu_pre,
    output  [FPLEN-1:0]   fs1_data,
    output  [FPLEN-1:0]   fs2_data,
    output  [FPLEN-1:0]   fs3_data,
    output valid_execution,
    output illegal_config,
    input scan_mode,
    output [3:0] float_control,
    output halt_req,
    output[2:0]fpu_sel
    );

    // Internal Wire and Reg decleration
       wire [114:0] control_signals;
       reg [114:0] control_signals_r;
       wire [4:0] fs1_addr, fs2_addr, fs3_addr;
       wire [FPLEN-1:0] fs1_data_w, fs2_data_w, fs3_data_w;
       wire [4:0] fd_reg;
       wire [1:0] fdest_pkg; // bit 1 = Floating Load, bit 0 = Floating Execution

       // Floating Destination Register FLops
       rvdffsc    #(5) fd_reg_ff_x (.clk(clk), .rst_l(rst_l), .en(valid_execution & control_signals[51] & fpu_active), .clear(((~valid_execution | ~fpu_active) & fpu_complete)), .din(control_signals[57] ? instr[11:7] : 5'h00), .dout(fd_reg));

       //rvdffsc    #(5) fd_reg_ff_wb (.clk(clk), .rst_l(rst_l), .en(fpu_complete_w), .clear(~fpu_active & ~fpu_complete_w & fpu_complete), .din(fd_reg_x), .dout(fd_reg));

       // Floating Destination write signal
       rvdffsc    #(2) fdest_pkg_ff_x (.clk(clk), .rst_l(rst_l), .en(valid_execution & control_signals[51] & fpu_active), .clear(((~valid_execution | ~fpu_active) & fpu_complete)), .din({control_signals[113],(control_signals[57] & ~control_signals[112])}), .dout(fdest_pkg));

       //rvdffsc    #(2) fdest_pkg_ff_wb (.clk(clk), .rst_l(rst_l), .en(fpu_complete_w), .clear(~fpu_active & ~fpu_complete_w & fpu_complete), .din(fdest_pkg_x), .dout(fdest_pkg));


    // Initiating Floating Decode Controller
       FPU_dec_ctl FPU_decode_controller (
                         .fpu_active(fpu_active),
                            .instr(instr),
                            .out(control_signals)
                         );


    // Initiating Floating Point Register File
       FPU_fpr_ctl floating_point_register_file (
                         .clk(clk),
                         .rst_l(rst_l),
                         .rden0(control_signals[54]),
                         .rden1(control_signals[55]),
                         .rden2(control_signals[56]),
                         .raddr0(fs1_addr),
                         .raddr1(fs2_addr),
                         .raddr2(fs3_addr),
                         .wen0(fpu_complete & fdest_pkg[0]), // single cycle port
                         .waddr0(fd_reg),
                         .wd0(fpu_result_1),
                         .rd0(fs1_data_w),         // read data
                         .rd1(fs2_data_w),
                         .rd2(fs3_data_w),
                      .scan_mode(scan_mode)
                         );


       assign illegal_instr = (rst_l == 1'b0) ? 1'b0 : ((fpu_active) & (control_signals[51] == 1'b0) & (~control_signals_r[51])) ? 1'b1 : 1'b0;

       // For half precision
       assign valid_execution = (rst_l == 1'b0) ? 1'b0 : (illegal_instr) ? 1'b0 : (fpu_active & control_signals[92] & control_signals_r[92] & ~control_signals[91]  & ~control_signals_r[91]) ? 1'b0 : (fpu_active & (control_signals[91] | control_signals_r[91])) ? 1'b1 : 1'b0;

       assign scalar_control = (rst_l == 1'b0) ? 3'b00 : control_signals[2:0];  // Contain the active signals for rs1, rs2, rd

       // for half precision
       assign illegal_config = (rst_l == 1'b0) ? 1'b0 : (fpu_active & (control_signals[89] | control_signals[90])) ? 1'b1 :  1'b0;

       // Scalar Register address
       assign rs1_address = (rst_l == 1'b0) ? 5'h00 : (valid_execution | control_signals[10]) ? instr[19:15] : 5'h00;
       assign rs2_address = (rst_l == 1'b0) ? 5'h00 : (valid_execution | control_signals[10]) ? instr[24:20] : 5'h00;
       assign rd_address  = (rst_l == 1'b0) ? 5'h00 : (valid_execution | control_signals[10]) ? instr[11:7]  : 5'h00;

       // Floating Control
       assign float_control = (rst_l == 1'b0) ? 4'b0000 : control_signals[57:54];  // Contain the active signals for fs1, fs2, fs3 and fd
       // Floating Point Register address
       assign fs1_addr = (rst_l == 1'b0) ? 5'h00 : (valid_execution & control_signals[54]) ? instr[19:15] : 5'h00;
       assign fs2_addr = (rst_l == 1'b0) ? 5'h00 : (valid_execution & control_signals[55]) ? instr[24:20] : 5'h00;
       assign fs3_addr = (rst_l == 1'b0) ? 5'h00 : (valid_execution & control_signals[56]) ? instr[31:27] : 5'h00;
       // Scalar or Vector operation signals
       assign fpu_sel = (rst_l == 1'b0 | illegal_config) ? 3'h0 : (valid_execution & fpu_active & control_signals[51]) ? {control_signals[93:92],control_signals[74]} : (~valid_execution | ~fpu_active | fpu_complete) ? 3'h0 : 3'h0;

       always @(posedge clk) begin
          if(rst_l == 1'b0 | illegal_config)
          begin
             control_signals_r <= 114'h0;
          end

          else
          begin
             // Execution Unit Valid signals and operands
             if((valid_execution & control_signals[51] & fpu_active))
             begin
                control_signals_r <= control_signals;
             end
             else if((~valid_execution) | ((~fpu_active) & (fpu_complete)))
             begin
                control_signals_r <= 114'h0;
             end
             else
             begin
                control_signals_r <= control_signals_r;
             end
          end
       end

    // FP Execution Operands
    assign fs1_data = (rst_l == 1'b0 | illegal_config) ? {FPLEN{1'b0}} : (valid_execution & control_signals[51] & fpu_active) ? fs1_data_w : (~valid_execution | ~fpu_active | fpu_complete) ? {FPLEN{1'b0}} : {FPLEN{1'b0}};

    assign fs2_data = (rst_l == 1'b0 | illegal_config) ? {FPLEN{1'b0}} : (valid_execution & control_signals[51] & fpu_active) ? fs2_data_w : (~valid_execution | ~fpu_active | fpu_complete) ? {FPLEN{1'b0}} : {FPLEN{1'b0}};

    assign fs3_data = (rst_l == 1'b0 | illegal_config) ? {FPLEN{1'b0}} : (valid_execution & control_signals[51] & fpu_active) ? fs3_data_w : (~valid_execution | ~fpu_active | fpu_complete) ? {FPLEN{1'b0}} : {FPLEN{1'b0}};

    // Scalar Floating point Control Signals
    assign sfpu_op = (rst_l == 1'b0 | illegal_config) ? 24'h0 : (valid_execution & fpu_active & control_signals[51] & control_signals[92]) ? {control_signals[32:31],control_signals[105:98],control_signals[88:75]} : (~valid_execution | ~fpu_active | fpu_complete) ? 24'h0 : 24'h0;

    // Floating Rounding mode
    assign fpu_rnd = (rst_l == 1'b0 | illegal_config) ? 3'h0 : (valid_execution & fpu_active & control_signals[51] & control_signals[92]) ? instr[14:12] : (~valid_execution | ~fpu_active | fpu_complete) ? 3'h0 : 3'h0;

    // Precision info {half,double,single}
    assign fpu_pre = (rst_l == 1'b0 | illegal_config) ? 3'h0 : (valid_execution & fpu_active & control_signals[51]) ? control_signals[91:89] : (~valid_execution | ~fpu_active | fpu_complete) ? 3'h0 : 3'h0;

    // Halt the core when fdiv/fsqrt
    assign halt_req = (rst_l == 1'b0 | illegal_config) ? 1'b0 : (control_signals[78] | control_signals[79]);


 endmodule
	module FPU_decode #(parameter FPLEN = 16)
	(
	input clk,
	input rst_l,
	input [31:0] instr,
	input fpu_active,
	input fpu_complete,
	input [FPLEN-1:0]fpu_result_1,
	output [2:0] scalar_control,
	output [4:0] rs1_address,
	output [4:0] rs2_address,
	output [4:0] rd_address,
	output illegal_instr,
	output [23:0] sfpu_op,
	output [2:0] fpu_rnd,
	output [2:0] fpu_pre,
	output [FPLEN-1:0] fs1_data,
	output [FPLEN-1:0] fs2_data,
	output [FPLEN-1:0] fs3_data,
	output valid_execution,
	output illegal_config,
	input scan_mode,
	output [3:0] float_control,
	output halt_req,
	output[2:0]fpu_sel
	);

	// Internal Wire and Reg decleration
	wire [114:0] control_signals;
	reg [114:0] control_signals_r;
	wire [4:0] fs1_addr, fs2_addr, fs3_addr;
	wire [FPLEN-1:0] fs1_data_w, fs2_data_w, fs3_data_w;
	wire [4:0] fd_reg;
	wire [1:0] fdest_pkg; // bit 1 = Floating Load, bit 0 = Floating Execution

	// Floating Destination Register FLops
	rvdffsc #(5) fd_reg_ff_x (.clk(clk), .rst_l(rst_l), .en(valid_execution & control_signals[51] & fpu_active), .clear(((~valid_execution \| ~fpu_active) & fpu_complete)), .din(control_signals[57] ? instr[11:7] : 5'h00), .dout(fd_reg));

	//rvdffsc #(5) fd_reg_ff_wb (.clk(clk), .rst_l(rst_l), .en(fpu_complete_w), .clear(~fpu_active & ~fpu_complete_w & fpu_complete), .din(fd_reg_x), .dout(fd_reg));

	// Floating Destination write signal
	rvdffsc #(2) fdest_pkg_ff_x (.clk(clk), .rst_l(rst_l), .en(valid_execution & control_signals[51] & fpu_active), .clear(((~valid_execution \| ~fpu_active) & fpu_complete)), .din({control_signals[113],(control_signals[57] & ~control_signals[112])}), .dout(fdest_pkg));

	//rvdffsc #(2) fdest_pkg_ff_wb (.clk(clk), .rst_l(rst_l), .en(fpu_complete_w), .clear(~fpu_active & ~fpu_complete_w & fpu_complete), .din(fdest_pkg_x), .dout(fdest_pkg));



	// Initiating Floating Decode Controller
	FPU_dec_ctl FPU_decode_controller (
	.fpu_active(fpu_active),
	.instr(instr),
	.out(control_signals)
	);


	// Initiating Floating Point Register File
	FPU_fpr_ctl floating_point_register_file (
	.clk(clk),
	.rst_l(rst_l),
	.rden0(control_signals[54]),
	.rden1(control_signals[55]),
	.rden2(control_signals[56]),
	.raddr0(fs1_addr),
	.raddr1(fs2_addr),
	.raddr2(fs3_addr),
	.wen0(fpu_complete & fdest_pkg[0]), // single cycle port
	.waddr0(fd_reg),
	.wd0(fpu_result_1),
	.rd0(fs1_data_w), // read data
	.rd1(fs2_data_w),
	.rd2(fs3_data_w),
	.scan_mode(scan_mode)
	);



	assign illegal_instr = (rst_l == 1'b0) ? 1'b0 : ((fpu_active) & (control_signals[51] == 1'b0) & (~control_signals_r[51])) ? 1'b1 : 1'b0;

	// For half precision
	assign valid_execution = (rst_l == 1'b0) ? 1'b0 : (illegal_instr) ? 1'b0 : (fpu_active & control_signals[92] & control_signals_r[92] & ~control_signals[91] & ~control_signals_r[91]) ? 1'b0 : (fpu_active & (control_signals[91] \| control_signals_r[91])) ? 1'b1 : 1'b0;

	assign scalar_control = (rst_l == 1'b0) ? 3'b00 : control_signals[2:0]; // Contain the active signals for rs1, rs2, rd

	// for half precision
	assign illegal_config = (rst_l == 1'b0) ? 1'b0 : (fpu_active & (control_signals[89] \| control_signals[90])) ? 1'b1 : 1'b0;

	// Scalar Register address
	assign rs1_address = (rst_l == 1'b0) ? 5'h00 : (valid_execution \| control_signals[10]) ? instr[19:15] : 5'h00;
	assign rs2_address = (rst_l == 1'b0) ? 5'h00 : (valid_execution \| control_signals[10]) ? instr[24:20] : 5'h00;
	assign rd_address = (rst_l == 1'b0) ? 5'h00 : (valid_execution \| control_signals[10]) ? instr[11:7] : 5'h00;

	// Floating Control
	assign float_control = (rst_l == 1'b0) ? 4'b0000 : control_signals[57:54]; // Contain the active signals for fs1, fs2, fs3 and fd
	// Floating Point Register address
	assign fs1_addr = (rst_l == 1'b0) ? 5'h00 : (valid_execution & control_signals[54]) ? instr[19:15] : 5'h00;
	assign fs2_addr = (rst_l == 1'b0) ? 5'h00 : (valid_execution & control_signals[55]) ? instr[24:20] : 5'h00;
	assign fs3_addr = (rst_l == 1'b0) ? 5'h00 : (valid_execution & control_signals[56]) ? instr[31:27] : 5'h00;
	// Scalar or Vector operation signals
	assign fpu_sel = (rst_l == 1'b0 \| illegal_config) ? 3'h0 : (valid_execution & fpu_active & control_signals[51]) ? {control_signals[93:92],control_signals[74]} : (~valid_execution \| ~fpu_active \| fpu_complete) ? 3'h0 : 3'h0;

	always @(posedge clk) begin
	if(rst_l == 1'b0 \| illegal_config)
	begin
	control_signals_r <= 114'h0;
	end

	else
	begin
	// Execution Unit Valid signals and operands
	if((valid_execution & control_signals[51] & fpu_active))
	begin
	control_signals_r <= control_signals;
	end
	else if((~valid_execution) \| ((~fpu_active) & (fpu_complete)))
	begin
	control_signals_r <= 114'h0;
	end
	else
	begin
	control_signals_r <= control_signals_r;
	end
	end
	end

	// FP Execution Operands
	assign fs1_data = (rst_l == 1'b0 \| illegal_config) ? {FPLEN{1'b0}} : (valid_execution & control_signals[51] & fpu_active) ? fs1_data_w : (~valid_execution \| ~fpu_active \| fpu_complete) ? {FPLEN{1'b0}} : {FPLEN{1'b0}};

	assign fs2_data = (rst_l == 1'b0 \| illegal_config) ? {FPLEN{1'b0}} : (valid_execution & control_signals[51] & fpu_active) ? fs2_data_w : (~valid_execution \| ~fpu_active \| fpu_complete) ? {FPLEN{1'b0}} : {FPLEN{1'b0}};

	assign fs3_data = (rst_l == 1'b0 \| illegal_config) ? {FPLEN{1'b0}} : (valid_execution & control_signals[51] & fpu_active) ? fs3_data_w : (~valid_execution \| ~fpu_active \| fpu_complete) ? {FPLEN{1'b0}} : {FPLEN{1'b0}};

	// Scalar Floating point Control Signals
	assign sfpu_op = (rst_l == 1'b0 \| illegal_config) ? 24'h0 : (valid_execution & fpu_active & control_signals[51] & control_signals[92]) ? {control_signals[32:31],control_signals[105:98],control_signals[88:75]} : (~valid_execution \| ~fpu_active \| fpu_complete) ? 24'h0 : 24'h0;

	// Floating Rounding mode
	assign fpu_rnd = (rst_l == 1'b0 \| illegal_config) ? 3'h0 : (valid_execution & fpu_active & control_signals[51] & control_signals[92]) ? instr[14:12] : (~valid_execution \| ~fpu_active \| fpu_complete) ? 3'h0 : 3'h0;

	// Precision info {half,double,single}
	assign fpu_pre = (rst_l == 1'b0 \| illegal_config) ? 3'h0 : (valid_execution & fpu_active & control_signals[51]) ? control_signals[91:89] : (~valid_execution \| ~fpu_active \| fpu_complete) ? 3'h0 : 3'h0;

	// Halt the core when fdiv/fsqrt
	assign halt_req = (rst_l == 1'b0 \| illegal_config) ? 1'b0 : (control_signals[78] \| control_signals[79]);



	endmodule