verilog/rtl/ibex_multdiv_slow.v - third_party/shuttle/sky130/mpw-002/slot-012 - Git at Google

 module ibex_multdiv_slow (
 	clk,
 	rst_n,
 	mult_en_i,
 	div_en_i,
 	operator_i,
 	signed_mode_i,
 	op_a_i,
 	op_b_i,
 	alu_adder_ext_i,
 	alu_adder_i,
 	equal_to_zero,
 	alu_operand_a_o,
 	alu_operand_b_o,
 	multdiv_result_o,
 	ready_o
 );
 	input wire clk;
 	input wire rst_n;
 	input wire mult_en_i;
 	input wire div_en_i;
 	input md_op_e operator_i;
 	input wire [1:0] signed_mode_i;
 	input wire [31:0] op_a_i;
 	input wire [31:0] op_b_i;
 	input wire [33:0] alu_adder_ext_i;
 	input wire [31:0] alu_adder_i;
 	input wire equal_to_zero;
 	output reg [32:0] alu_operand_a_o;
 	output reg [32:0] alu_operand_b_o;
 	output reg [31:0] multdiv_result_o;
 	output wire ready_o;
 	reg [4:0] multdiv_state_q;
 	reg [4:0] multdiv_state_d;
 	wire [4:0] multdiv_state_m1;
 	reg [2:0] curr_state_q;
 	reg [2:0] curr_state_d;
 	reg [32:0] accum_window_q;
 	reg [32:0] accum_window_d;
 	wire [32:0] res_adder_l;
 	wire [32:0] res_adder_h;
 	reg [32:0] op_b_shift_q;
 	reg [32:0] op_b_shift_d;
 	reg [32:0] op_a_shift_q;
 	reg [32:0] op_a_shift_d;
 	wire [32:0] op_a_ext;
 	wire [32:0] op_b_ext;
 	wire [32:0] one_shift;
 	wire [32:0] op_a_bw_pp;
 	wire [32:0] op_a_bw_last_pp;
 	wire [31:0] b_0;
 	wire sign_a;
 	wire sign_b;
 	wire [32:0] next_reminder;
 	wire [32:0] next_quotient;
 	wire [32:0] op_remainder;
 	reg [31:0] op_numerator_q;
 	reg [31:0] op_numerator_d;
 	wire is_greater_equal;
 	wire div_change_sign;
 	wire rem_change_sign;
 	assign res_adder_l = alu_adder_ext_i[32:0];
 	assign res_adder_h = alu_adder_ext_i[33:1];
 	localparam [2:0] MD_ABS_A = 1;
 	localparam [2:0] MD_ABS_B = 2;
 	localparam [2:0] MD_CHANGE_SIGN = 5;
 	localparam [2:0] MD_IDLE = 0;
 	localparam [2:0] MD_LAST = 4;
 	always @(*) begin
 		alu_operand_a_o = accum_window_q;
 		multdiv_result_o = (div_en_i ? accum_window_q[31:0] : res_adder_l);
 		case (operator_i)
 			MD_OP_MULL: alu_operand_b_o = op_a_bw_pp;
 			MD_OP_MULH: alu_operand_b_o = (curr_state_q == MD_LAST ? op_a_bw_last_pp : op_a_bw_pp);
 			default:
 				case (curr_state_q)
 					MD_IDLE: begin
 						alu_operand_a_o = 33'b000000000000000000000000000000001;
 						alu_operand_b_o = {~op_b_i, 1'b1};
 					end
 					MD_ABS_A: begin
 						alu_operand_a_o = 33'b000000000000000000000000000000001;
 						alu_operand_b_o = {~op_a_i, 1'b1};
 					end
 					MD_ABS_B: begin
 						alu_operand_a_o = 33'b000000000000000000000000000000001;
 						alu_operand_b_o = {~op_b_i, 1'b1};
 					end
 					MD_CHANGE_SIGN: begin
 						alu_operand_a_o = 33'b000000000000000000000000000000001;
 						alu_operand_b_o = {~accum_window_q[31:0], 1'b1};
 					end
 					default: begin
 						alu_operand_a_o = {accum_window_q[31:0], 1'b1};
 						alu_operand_b_o = {~op_b_shift_q[31:0], 1'b1};
 					end
 				endcase
 		endcase
 	end
 	assign is_greater_equal = ((accum_window_q[31] ^ op_b_shift_q[31]) == 1'b0 ? res_adder_h[31] == 1'b0 : accum_window_q[31]);
 	assign one_shift = 33'b000000000000000000000000000000001 << multdiv_state_q;
 	assign next_reminder = (is_greater_equal ? res_adder_h : op_remainder);
 	assign next_quotient = (is_greater_equal ? op_a_shift_q | one_shift : op_a_shift_q);
 	assign b_0 = {32 {op_b_shift_q[0]}};
 	assign op_a_bw_pp = {~(op_a_shift_q[32] & op_b_shift_q[0]), op_a_shift_q[31:0] & b_0};
 	assign op_a_bw_last_pp = {op_a_shift_q[32] & op_b_shift_q[0], ~(op_a_shift_q[31:0] & b_0)};
 	assign sign_a = op_a_i[31] & signed_mode_i[0];
 	assign sign_b = op_b_i[31] & signed_mode_i[1];
 	assign op_a_ext = {sign_a, op_a_i};
 	assign op_b_ext = {sign_b, op_b_i};
 	assign op_remainder = accum_window_q[32:0];
 	assign multdiv_state_m1 = multdiv_state_q - 5'h01;
 	assign div_change_sign = sign_a ^ sign_b;
 	assign rem_change_sign = sign_a;
 	always @(posedge clk or negedge rst_n) begin : proc_multdiv_state_q
 		if (!rst_n) begin
 			multdiv_state_q <= 5'h00;
 			accum_window_q <= 33'h000000000;
 			op_b_shift_q <= 33'h000000000;
 			op_a_shift_q <= 33'h000000000;
 			op_numerator_q <= 32'h00000000;
 			curr_state_q <= MD_IDLE;
 		end
 		else begin
 			multdiv_state_q <= multdiv_state_d;
 			accum_window_q <= accum_window_d;
 			op_b_shift_q <= op_b_shift_d;
 			op_a_shift_q <= op_a_shift_d;
 			op_numerator_q <= op_numerator_d;
 			curr_state_q <= curr_state_d;
 		end
 	end
 	localparam [2:0] MD_COMP = 3;
 	localparam [2:0] MD_FINISH = 6;
 	always @(*) begin
 		multdiv_state_d = multdiv_state_q;
 		accum_window_d = accum_window_q;
 		op_b_shift_d = op_b_shift_q;
 		op_a_shift_d = op_a_shift_q;
 		op_numerator_d = op_numerator_q;
 		curr_state_d = curr_state_q;
 		if (mult_en_i || div_en_i)
 			case (curr_state_q)
 				MD_IDLE: begin
 					case (operator_i)
 						MD_OP_MULL: begin
 							op_a_shift_d = op_a_ext << 1;
 							accum_window_d = {~(op_a_ext[32] & op_b_i[0]), op_a_ext[31:0] & {32 {op_b_i[0]}}};
 							op_b_shift_d = op_b_ext >> 1;
 							curr_state_d = MD_COMP;
 						end
 						MD_OP_MULH: begin
 							op_a_shift_d = op_a_ext;
 							accum_window_d = {1'b1, ~(op_a_ext[32] & op_b_i[0]), op_a_ext[31:1] & {31 {op_b_i[0]}}};
 							op_b_shift_d = op_b_ext >> 1;
 							curr_state_d = MD_COMP;
 						end
 						MD_OP_DIV: begin
 							accum_window_d = {33 {1'b1}};
 							curr_state_d = (equal_to_zero ? MD_FINISH : MD_ABS_A);
 						end
 						default: begin
 							accum_window_d = op_a_ext;
 							curr_state_d = (equal_to_zero ? MD_FINISH : MD_ABS_A);
 						end
 					endcase
 					multdiv_state_d = 5'd31;
 				end
 				MD_ABS_A: begin
 					op_a_shift_d = {33 {1'sb0}};
 					op_numerator_d = (sign_a ? alu_adder_i : op_a_i);
 					curr_state_d = MD_ABS_B;
 				end
 				MD_ABS_B: begin
 					accum_window_d = {32'h00000000, op_numerator_q[31]};
 					op_b_shift_d = (sign_b ? alu_adder_i : op_b_i);
 					curr_state_d = MD_COMP;
 				end
 				MD_COMP: begin
 					multdiv_state_d = multdiv_state_m1;
 					case (operator_i)
 						MD_OP_MULL: begin
 							accum_window_d = res_adder_l;
 							op_a_shift_d = op_a_shift_q << 1;
 							op_b_shift_d = op_b_shift_q >> 1;
 						end
 						MD_OP_MULH: begin
 							accum_window_d = res_adder_h;
 							op_a_shift_d = op_a_shift_q;
 							op_b_shift_d = op_b_shift_q >> 1;
 						end
 						default: begin
 							accum_window_d = {next_reminder[31:0], op_numerator_q[multdiv_state_m1]};
 							op_a_shift_d = next_quotient;
 						end
 					endcase
 					curr_state_d = (multdiv_state_q == 5'd1 ? MD_LAST : MD_COMP);
 				end
 				MD_LAST:
 					case (operator_i)
 						MD_OP_MULL: begin
 							accum_window_d = res_adder_l;
 							curr_state_d = MD_IDLE;
 						end
 						MD_OP_MULH: begin
 							accum_window_d = res_adder_l;
 							curr_state_d = MD_IDLE;
 						end
 						MD_OP_DIV: begin
 							accum_window_d = next_quotient;
 							curr_state_d = MD_CHANGE_SIGN;
 						end
 						default: begin
 							accum_window_d = {1'b0, next_reminder[31:0]};
 							curr_state_d = MD_CHANGE_SIGN;
 						end
 					endcase
 				MD_CHANGE_SIGN: begin
 					curr_state_d = MD_FINISH;
 					case (operator_i)
 						MD_OP_DIV: accum_window_d = (div_change_sign ? alu_adder_i : accum_window_q);
 						default: accum_window_d = (rem_change_sign ? alu_adder_i : accum_window_q);
 					endcase
 				end
 				MD_FINISH: curr_state_d = MD_IDLE;
 				default:
 					;
 			endcase
 	end
 	assign ready_o = (curr_state_q == MD_FINISH) | ((curr_state_q == MD_LAST) & ((operator_i == MD_OP_MULL) | (operator_i == MD_OP_MULH)));
 endmodule
	module ibex_multdiv_slow (
	clk,
	rst_n,
	mult_en_i,
	div_en_i,
	operator_i,
	signed_mode_i,
	op_a_i,
	op_b_i,
	alu_adder_ext_i,
	alu_adder_i,
	equal_to_zero,
	alu_operand_a_o,
	alu_operand_b_o,
	multdiv_result_o,
	ready_o
	);
	input wire clk;
	input wire rst_n;
	input wire mult_en_i;
	input wire div_en_i;
	input md_op_e operator_i;
	input wire [1:0] signed_mode_i;
	input wire [31:0] op_a_i;
	input wire [31:0] op_b_i;
	input wire [33:0] alu_adder_ext_i;
	input wire [31:0] alu_adder_i;
	input wire equal_to_zero;
	output reg [32:0] alu_operand_a_o;
	output reg [32:0] alu_operand_b_o;
	output reg [31:0] multdiv_result_o;
	output wire ready_o;
	reg [4:0] multdiv_state_q;
	reg [4:0] multdiv_state_d;
	wire [4:0] multdiv_state_m1;
	reg [2:0] curr_state_q;
	reg [2:0] curr_state_d;
	reg [32:0] accum_window_q;
	reg [32:0] accum_window_d;
	wire [32:0] res_adder_l;
	wire [32:0] res_adder_h;
	reg [32:0] op_b_shift_q;
	reg [32:0] op_b_shift_d;
	reg [32:0] op_a_shift_q;
	reg [32:0] op_a_shift_d;
	wire [32:0] op_a_ext;
	wire [32:0] op_b_ext;
	wire [32:0] one_shift;
	wire [32:0] op_a_bw_pp;
	wire [32:0] op_a_bw_last_pp;
	wire [31:0] b_0;
	wire sign_a;
	wire sign_b;
	wire [32:0] next_reminder;
	wire [32:0] next_quotient;
	wire [32:0] op_remainder;
	reg [31:0] op_numerator_q;
	reg [31:0] op_numerator_d;
	wire is_greater_equal;
	wire div_change_sign;
	wire rem_change_sign;
	assign res_adder_l = alu_adder_ext_i[32:0];
	assign res_adder_h = alu_adder_ext_i[33:1];
	localparam [2:0] MD_ABS_A = 1;
	localparam [2:0] MD_ABS_B = 2;
	localparam [2:0] MD_CHANGE_SIGN = 5;
	localparam [2:0] MD_IDLE = 0;
	localparam [2:0] MD_LAST = 4;
	always @(*) begin
	alu_operand_a_o = accum_window_q;
	multdiv_result_o = (div_en_i ? accum_window_q[31:0] : res_adder_l);
	case (operator_i)
	MD_OP_MULL: alu_operand_b_o = op_a_bw_pp;
	MD_OP_MULH: alu_operand_b_o = (curr_state_q == MD_LAST ? op_a_bw_last_pp : op_a_bw_pp);
	default:
	case (curr_state_q)
	MD_IDLE: begin
	alu_operand_a_o = 33'b000000000000000000000000000000001;
	alu_operand_b_o = {~op_b_i, 1'b1};
	end
	MD_ABS_A: begin
	alu_operand_a_o = 33'b000000000000000000000000000000001;
	alu_operand_b_o = {~op_a_i, 1'b1};
	end
	MD_ABS_B: begin
	alu_operand_a_o = 33'b000000000000000000000000000000001;
	alu_operand_b_o = {~op_b_i, 1'b1};
	end
	MD_CHANGE_SIGN: begin
	alu_operand_a_o = 33'b000000000000000000000000000000001;
	alu_operand_b_o = {~accum_window_q[31:0], 1'b1};
	end
	default: begin
	alu_operand_a_o = {accum_window_q[31:0], 1'b1};
	alu_operand_b_o = {~op_b_shift_q[31:0], 1'b1};
	end
	endcase
	endcase
	end
	assign is_greater_equal = ((accum_window_q[31] ^ op_b_shift_q[31]) == 1'b0 ? res_adder_h[31] == 1'b0 : accum_window_q[31]);
	assign one_shift = 33'b000000000000000000000000000000001 << multdiv_state_q;
	assign next_reminder = (is_greater_equal ? res_adder_h : op_remainder);
	assign next_quotient = (is_greater_equal ? op_a_shift_q \| one_shift : op_a_shift_q);
	assign b_0 = {32 {op_b_shift_q[0]}};
	assign op_a_bw_pp = {~(op_a_shift_q[32] & op_b_shift_q[0]), op_a_shift_q[31:0] & b_0};
	assign op_a_bw_last_pp = {op_a_shift_q[32] & op_b_shift_q[0], ~(op_a_shift_q[31:0] & b_0)};
	assign sign_a = op_a_i[31] & signed_mode_i[0];
	assign sign_b = op_b_i[31] & signed_mode_i[1];
	assign op_a_ext = {sign_a, op_a_i};
	assign op_b_ext = {sign_b, op_b_i};
	assign op_remainder = accum_window_q[32:0];
	assign multdiv_state_m1 = multdiv_state_q - 5'h01;
	assign div_change_sign = sign_a ^ sign_b;
	assign rem_change_sign = sign_a;
	always @(posedge clk or negedge rst_n) begin : proc_multdiv_state_q
	if (!rst_n) begin
	multdiv_state_q <= 5'h00;
	accum_window_q <= 33'h000000000;
	op_b_shift_q <= 33'h000000000;
	op_a_shift_q <= 33'h000000000;
	op_numerator_q <= 32'h00000000;
	curr_state_q <= MD_IDLE;
	end
	else begin
	multdiv_state_q <= multdiv_state_d;
	accum_window_q <= accum_window_d;
	op_b_shift_q <= op_b_shift_d;
	op_a_shift_q <= op_a_shift_d;
	op_numerator_q <= op_numerator_d;
	curr_state_q <= curr_state_d;
	end
	end
	localparam [2:0] MD_COMP = 3;
	localparam [2:0] MD_FINISH = 6;
	always @(*) begin
	multdiv_state_d = multdiv_state_q;
	accum_window_d = accum_window_q;
	op_b_shift_d = op_b_shift_q;
	op_a_shift_d = op_a_shift_q;
	op_numerator_d = op_numerator_q;
	curr_state_d = curr_state_q;
	if (mult_en_i \|\| div_en_i)
	case (curr_state_q)
	MD_IDLE: begin
	case (operator_i)
	MD_OP_MULL: begin
	op_a_shift_d = op_a_ext << 1;
	accum_window_d = {~(op_a_ext[32] & op_b_i[0]), op_a_ext[31:0] & {32 {op_b_i[0]}}};
	op_b_shift_d = op_b_ext >> 1;
	curr_state_d = MD_COMP;
	end
	MD_OP_MULH: begin
	op_a_shift_d = op_a_ext;
	accum_window_d = {1'b1, ~(op_a_ext[32] & op_b_i[0]), op_a_ext[31:1] & {31 {op_b_i[0]}}};
	op_b_shift_d = op_b_ext >> 1;
	curr_state_d = MD_COMP;
	end
	MD_OP_DIV: begin
	accum_window_d = {33 {1'b1}};
	curr_state_d = (equal_to_zero ? MD_FINISH : MD_ABS_A);
	end
	default: begin
	accum_window_d = op_a_ext;
	curr_state_d = (equal_to_zero ? MD_FINISH : MD_ABS_A);
	end
	endcase
	multdiv_state_d = 5'd31;
	end
	MD_ABS_A: begin
	op_a_shift_d = {33 {1'sb0}};
	op_numerator_d = (sign_a ? alu_adder_i : op_a_i);
	curr_state_d = MD_ABS_B;
	end
	MD_ABS_B: begin
	accum_window_d = {32'h00000000, op_numerator_q[31]};
	op_b_shift_d = (sign_b ? alu_adder_i : op_b_i);
	curr_state_d = MD_COMP;
	end
	MD_COMP: begin
	multdiv_state_d = multdiv_state_m1;
	case (operator_i)
	MD_OP_MULL: begin
	accum_window_d = res_adder_l;
	op_a_shift_d = op_a_shift_q << 1;
	op_b_shift_d = op_b_shift_q >> 1;
	end
	MD_OP_MULH: begin
	accum_window_d = res_adder_h;
	op_a_shift_d = op_a_shift_q;
	op_b_shift_d = op_b_shift_q >> 1;
	end
	default: begin
	accum_window_d = {next_reminder[31:0], op_numerator_q[multdiv_state_m1]};
	op_a_shift_d = next_quotient;
	end
	endcase
	curr_state_d = (multdiv_state_q == 5'd1 ? MD_LAST : MD_COMP);
	end
	MD_LAST:
	case (operator_i)
	MD_OP_MULL: begin
	accum_window_d = res_adder_l;
	curr_state_d = MD_IDLE;
	end
	MD_OP_MULH: begin
	accum_window_d = res_adder_l;
	curr_state_d = MD_IDLE;
	end
	MD_OP_DIV: begin
	accum_window_d = next_quotient;
	curr_state_d = MD_CHANGE_SIGN;
	end
	default: begin
	accum_window_d = {1'b0, next_reminder[31:0]};
	curr_state_d = MD_CHANGE_SIGN;
	end
	endcase
	MD_CHANGE_SIGN: begin
	curr_state_d = MD_FINISH;
	case (operator_i)
	MD_OP_DIV: accum_window_d = (div_change_sign ? alu_adder_i : accum_window_q);
	default: accum_window_d = (rem_change_sign ? alu_adder_i : accum_window_q);
	endcase
	end
	MD_FINISH: curr_state_d = MD_IDLE;
	default:
	;
	endcase
	end
	assign ready_o = (curr_state_q == MD_FINISH) \| ((curr_state_q == MD_LAST) & ((operator_i == MD_OP_MULL) \| (operator_i == MD_OP_MULH)));
	endmodule