Sturges/AutoVCoder_round1 · Datasets at Hugging Face

code stringlengths 35 6.69k	score float64 6.5 11.5
module start_for_Block_peSV_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.268805
module start_for_Block_peSV ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Block_peSV_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Block_peSV_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.268805
module start_for_comm_rehbi_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	8.134489
module start_for_comm_rehbi ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_comm_rehbi_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_comm_rehbi_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	8.134489
module start_for_comm_wribs_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	8.134489
module start_for_comm_wribs ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_comm_wribs_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_comm_wribs_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	8.134489
module start_for_convert_uint512_to_output_data_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.51107
module start_for_convert_uint512_to_output_data_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_convert_uint512_to_output_data_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_convert_uint512_to_output_data_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_16u_config2_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_16u_config2_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_16u_config2_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_16u_config2_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_2u_config2_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_2u_config2_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_2u_config2_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_2u_config2_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_2u_config4_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_2u_config4_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_2u_config4_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_2u_config4_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_2u_config6_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_2u_config6_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_2u_config6_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_2u_config6_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_5u_config2_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_5u_config2_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_5u_config2_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_5u_config2_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_5u_config3_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_5u_config3_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_5u_config3_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_5u_config3_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_8u_config2_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.51107
module start_for_conv_2d_cl_array_array_ap_fixed_8u_config2_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_8u_config2_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_8u_config2_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.51107
module start_for_create_bkb_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.571408
module start_for_create_bkb ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_create_bkb_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_create_bkb_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.571408
module start_for_CvtColoyd2_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.632817
module start_for_CvtColoyd2 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_CvtColoyd2_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_CvtColoyd2_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.632817
module start_for_Dilate2Ffa_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd8; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.990022
module start_for_Dilate2Ffa ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd8; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Dilate2Ffa_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Dilate2Ffa_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.990022
module start_for_Dilate_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd10; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.990022
module start_for_Dilate_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd10; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 5'd1; if (mOutPtr == 5'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 5'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 5'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Dilate_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Dilate_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.990022
module start_for_dram_C_D_to_app_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 32'd5; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.692455
module start_for_dram_C_D_to_app_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 32'd5; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_C_D_to_app_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_C_D_to_app_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.692455
module start_for_dram_data_caching_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 32'd5; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.692455
module start_for_dram_data_caching_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 32'd5; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_data_caching_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_data_caching_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.692455
module start_for_dram_read_delay_unit_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd4; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.692455
module start_for_dram_read_delay_unit_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd4; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_read_delay_unit_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_read_delay_unit_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.692455
module start_for_dram_read_req_time_marker_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.692455
module start_for_dram_read_req_time_marker_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_read_req_time_marker_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_read_req_time_marker_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.692455
module start_for_dram_read_throttle_unit_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.692455
module start_for_dram_read_throttle_unit_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_read_throttle_unit_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_read_throttle_unit_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.692455
module start_for_dram_write_delay_unit_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.692455
module start_for_dram_write_delay_unit_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_write_delay_unit_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_write_delay_unit_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.692455
module start_for_dram_write_throttle_unit_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd3; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.692455
module start_for_dram_write_throttle_unit_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd3; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_write_throttle_unit_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_write_throttle_unit_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.692455
module start_for_draw_mibkb_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.692455
module start_for_draw_mibkb ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_draw_mibkb_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_draw_mibkb_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.692455
module start_for_DuneDateRU_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.917611
module start_for_DuneDateRU ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_DuneDateRU_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_DuneDateRU_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.917611
module start_for_Duplicacud_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.794828
module start_for_Duplicacud ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Duplicacud_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Duplicacud_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.794828
module start_for_DuplicadEe_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.794828
module start_for_DuplicadEe ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_DuplicadEe_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_DuplicadEe_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.794828
module start_for_Duplicaibs_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.794828
module start_for_Duplicaibs ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Duplicaibs_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Duplicaibs_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.794828
module start_for_Duplicamb6_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.794828
module start_for_Duplicamb6 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Duplicamb6_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Duplicamb6_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.794828
module start_for_Erode_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd11; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.052016
module start_for_Erode_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd11; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 5'd1; if (mOutPtr == 5'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 5'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 5'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Erode_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Erode_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.052016
module start_for_find_bofYi_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd7; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.630138
module start_for_find_bofYi ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd7; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_find_bofYi_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_find_bofYi_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.630138
module start_for_find_bog8j_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd7; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.630138
module start_for_find_bog8j ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd7; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_find_bog8j_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_find_bog8j_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.630138
module start_for_Get_hsvzec_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.138401
module start_for_Get_hsvzec ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Get_hsvzec_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Get_hsvzec_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.138401
module start_for_linear_kbM_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.562962
module start_for_linear_kbM ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_linear_kbM_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_linear_kbM_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.562962
module start_for_linear_lbW_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.562962
module start_for_linear_lbW ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_linear_lbW_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_linear_lbW_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.562962
module start_for_linear_mb6_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.562962
module start_for_linear_mb6 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_linear_mb6_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_linear_mb6_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.562962
module start_for_linear_ncg_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.562962
module start_for_linear_ncg ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_linear_ncg_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_linear_ncg_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.562962
module start_for_lz77_encode_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.776847
module start_for_lz77_encode_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_lz77_encode_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_lz77_encode_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.776847
module start_for_Mat2AXIcud_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.585081
module start_for_Mat2AXIcud ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Mat2AXIcud_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Mat2AXIcud_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.585081
module start_for_Mat2AXIDeQ_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd12; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.585081
module start_for_Mat2AXIDeQ ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd12; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 5'd1; if (mOutPtr == 5'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 5'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 5'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Mat2AXIDeQ_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Mat2AXIDeQ_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.585081
module start_for_Mat2AXIg8j_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.585081
module start_for_Mat2AXIg8j ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Mat2AXIg8j_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Mat2AXIg8j_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.585081
module start_for_Mat2AXIhbi_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.585081
module start_for_Mat2AXIhbi ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Mat2AXIhbi_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Mat2AXIhbi_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.585081
module start_for_mat2veccud_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.69519
module start_for_mat2veccud ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_mat2veccud_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_mat2veccud_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.69519
module start_for_merger_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd3; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	6.971346
module start_for_merger_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd3; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_merger_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_merger_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	6.971346
module start_for_minus_vncg_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.106633
module start_for_minus_vncg ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vncg_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vncg_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.106633
module start_for_minus_vocq_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.106633
module start_for_minus_vocq ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vocq_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vocq_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.106633
module start_for_minus_vpcA_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.106633
module start_for_minus_vpcA ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vpcA_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vpcA_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.106633
module start_for_minus_vqcK_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.106633
module start_for_minus_vqcK ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vqcK_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vqcK_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.106633
module start_for_minus_vrcU_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.106633
module start_for_minus_vrcU ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vrcU_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vrcU_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.106633
module start_for_minus_vsc4_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.106633
module start_for_minus_vsc4 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vsc4_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vsc4_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.106633
module start_for_minus_vtde_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule	7.106633
module start_for_minus_vtde ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 \| internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 \| internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vtde_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vtde_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule	7.106633

module start_for_Block_peSV_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.268805

module start_for_Block_peSV ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Block_peSV_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Block_peSV_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.268805

module start_for_comm_rehbi_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

8.134489

module start_for_comm_rehbi ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_comm_rehbi_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_comm_rehbi_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

8.134489

module start_for_comm_wribs_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

8.134489

module start_for_comm_wribs ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_comm_wribs_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_comm_wribs_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

8.134489

module start_for_convert_uint512_to_output_data_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.51107

module start_for_convert_uint512_to_output_data_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_convert_uint512_to_output_data_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_convert_uint512_to_output_data_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

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module start_for_conv_2d_cl_array_array_ap_fixed_16u_config2_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_16u_config2_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_16u_config2_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_16u_config2_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_2u_config2_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_2u_config2_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_2u_config2_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_2u_config2_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

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module start_for_conv_2d_cl_array_array_ap_fixed_2u_config4_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_2u_config4_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_2u_config4_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_2u_config4_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_2u_config6_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_2u_config6_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_2u_config6_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_2u_config6_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_5u_config2_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_5u_config2_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_5u_config2_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_5u_config2_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_5u_config3_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_5u_config3_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_5u_config3_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_5u_config3_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_8u_config2_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.51107

module start_for_conv_2d_cl_array_array_ap_fixed_8u_config2_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_conv_2d_cl_array_array_ap_fixed_8u_config2_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_conv_2d_cl_array_array_ap_fixed_8u_config2_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.51107

module start_for_create_bkb_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.571408

module start_for_create_bkb ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_create_bkb_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_create_bkb_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.571408

module start_for_CvtColoyd2_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.632817

module start_for_CvtColoyd2 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_CvtColoyd2_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_CvtColoyd2_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.632817

module start_for_Dilate2Ffa_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd8; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.990022

module start_for_Dilate2Ffa ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd8; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Dilate2Ffa_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Dilate2Ffa_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.990022

module start_for_Dilate_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd10; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.990022

module start_for_Dilate_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd10; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 5'd1; if (mOutPtr == 5'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 5'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 5'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Dilate_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Dilate_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.990022

module start_for_dram_C_D_to_app_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 32'd5; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.692455

module start_for_dram_C_D_to_app_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 32'd5; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_C_D_to_app_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_C_D_to_app_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.692455

module start_for_dram_data_caching_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 32'd5; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.692455

module start_for_dram_data_caching_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 32'd5; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_data_caching_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_data_caching_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.692455

module start_for_dram_read_delay_unit_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd4; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.692455

module start_for_dram_read_delay_unit_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd4; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_read_delay_unit_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_read_delay_unit_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.692455

module start_for_dram_read_req_time_marker_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.692455

module start_for_dram_read_req_time_marker_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_read_req_time_marker_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_read_req_time_marker_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

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module start_for_dram_read_throttle_unit_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

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module start_for_dram_read_throttle_unit_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_read_throttle_unit_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_read_throttle_unit_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

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module start_for_dram_write_delay_unit_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

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module start_for_dram_write_delay_unit_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_write_delay_unit_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_write_delay_unit_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

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module start_for_dram_write_throttle_unit_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd3; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

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module start_for_dram_write_throttle_unit_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd3; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_dram_write_throttle_unit_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_dram_write_throttle_unit_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

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module start_for_draw_mibkb_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

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module start_for_draw_mibkb ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_draw_mibkb_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_draw_mibkb_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

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module start_for_DuneDateRU_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

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module start_for_DuneDateRU ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_DuneDateRU_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_DuneDateRU_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

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module start_for_Duplicacud_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

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module start_for_Duplicacud ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Duplicacud_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Duplicacud_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

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module start_for_DuplicadEe_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

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module start_for_DuplicadEe ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_DuplicadEe_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_DuplicadEe_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

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module start_for_Duplicaibs_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.794828

module start_for_Duplicaibs ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Duplicaibs_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Duplicaibs_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.794828

module start_for_Duplicamb6_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.794828

module start_for_Duplicamb6 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Duplicamb6_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Duplicamb6_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.794828

module start_for_Erode_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd11; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.052016

module start_for_Erode_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd11; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 5'd1; if (mOutPtr == 5'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 5'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 5'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Erode_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Erode_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.052016

module start_for_find_bofYi_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd7; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.630138

module start_for_find_bofYi ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd7; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_find_bofYi_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_find_bofYi_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.630138

module start_for_find_bog8j_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd7; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.630138

module start_for_find_bog8j ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd7; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_find_bog8j_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_find_bog8j_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.630138

module start_for_Get_hsvzec_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.138401

module start_for_Get_hsvzec ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Get_hsvzec_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Get_hsvzec_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.138401

module start_for_linear_kbM_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.562962

module start_for_linear_kbM ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_linear_kbM_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_linear_kbM_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.562962

module start_for_linear_lbW_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.562962

module start_for_linear_lbW ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_linear_lbW_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_linear_lbW_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.562962

module start_for_linear_mb6_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.562962

module start_for_linear_mb6 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_linear_mb6_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_linear_mb6_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.562962

module start_for_linear_ncg_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.562962

module start_for_linear_ncg ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_linear_ncg_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_linear_ncg_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.562962

module start_for_lz77_encode_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.776847

module start_for_lz77_encode_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "auto"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 32'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_lz77_encode_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_lz77_encode_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.776847

module start_for_Mat2AXIcud_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.585081

module start_for_Mat2AXIcud ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd3; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Mat2AXIcud_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Mat2AXIcud_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.585081

module start_for_Mat2AXIDeQ_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd12; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.585081

module start_for_Mat2AXIDeQ ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd12; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 5'd1; if (mOutPtr == 5'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 5'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 5'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Mat2AXIDeQ_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Mat2AXIDeQ_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.585081

module start_for_Mat2AXIg8j_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.585081

module start_for_Mat2AXIg8j ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd3; parameter DEPTH = 4'd5; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 4'd1; if (mOutPtr == 4'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 4'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 4'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Mat2AXIg8j_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Mat2AXIg8j_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.585081

module start_for_Mat2AXIhbi_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.585081

module start_for_Mat2AXIhbi ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 3'd4; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 3'd1; if (mOutPtr == 3'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 3'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 3'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_Mat2AXIhbi_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_Mat2AXIhbi_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.585081

module start_for_mat2veccud_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.69519

module start_for_mat2veccud ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_mat2veccud_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_mat2veccud_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.69519

module start_for_merger_U0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd3; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

6.971346

module start_for_merger_U0 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd2; parameter DEPTH = 32'd3; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = {(ADDR_WIDTH + 1) {1'b1}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 1; if (mOutPtr == 0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_merger_U0_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_merger_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

6.971346

module start_for_minus_vncg_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.106633

module start_for_minus_vncg ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vncg_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vncg_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.106633

module start_for_minus_vocq_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.106633

module start_for_minus_vocq ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vocq_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vocq_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.106633

module start_for_minus_vpcA_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.106633

module start_for_minus_vpcA ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vpcA_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vpcA_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.106633

module start_for_minus_vqcK_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.106633

module start_for_minus_vqcK ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vqcK_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vqcK_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.106633

module start_for_minus_vrcU_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.106633

module start_for_minus_vrcU ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vrcU_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vrcU_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.106633

module start_for_minus_vsc4_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.106633

module start_for_minus_vsc4 ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vsc4_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vsc4_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.106633

module start_for_minus_vtde_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input [DATA_WIDTH-1:0] data; input ce; input [ADDR_WIDTH-1:0] a; output [DATA_WIDTH-1:0] q; reg [DATA_WIDTH-1:0] SRL_SIG[0:DEPTH-1]; integer i; always @(posedge clk) begin if (ce) begin for (i = 0; i < DEPTH - 1; i = i + 1) SRL_SIG[i+1] <= SRL_SIG[i]; SRL_SIG[0] <= data; end end assign q = SRL_SIG[a]; endmodule

7.106633

module start_for_minus_vtde ( clk, reset, if_empty_n, if_read_ce, if_read, if_dout, if_full_n, if_write_ce, if_write, if_din ); parameter MEM_STYLE = "shiftreg"; parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd1; parameter DEPTH = 2'd2; input clk; input reset; output if_empty_n; input if_read_ce; input if_read; output [DATA_WIDTH - 1:0] if_dout; output if_full_n; input if_write_ce; input if_write; input [DATA_WIDTH - 1:0] if_din; wire [ADDR_WIDTH - 1:0] shiftReg_addr; wire [DATA_WIDTH - 1:0] shiftReg_data, shiftReg_q; wire shiftReg_ce; reg [ADDR_WIDTH:0] mOutPtr = ~{(ADDR_WIDTH + 1) {1'b0}}; reg internal_empty_n = 0, internal_full_n = 1; assign if_empty_n = internal_empty_n; assign if_full_n = internal_full_n; assign shiftReg_data = if_din; assign if_dout = shiftReg_q; always @(posedge clk) begin if (reset == 1'b1) begin mOutPtr <= ~{ADDR_WIDTH + 1{1'b0}}; internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else begin if (((if_read & if_read_ce) == 1 & internal_empty_n == 1) && ((if_write & if_write_ce) == 0 | internal_full_n == 0)) begin mOutPtr <= mOutPtr - 2'd1; if (mOutPtr == 2'd0) internal_empty_n <= 1'b0; internal_full_n <= 1'b1; end else if (((if_read & if_read_ce) == 0 | internal_empty_n == 0) && ((if_write & if_write_ce) == 1 & internal_full_n == 1)) begin mOutPtr <= mOutPtr + 2'd1; internal_empty_n <= 1'b1; if (mOutPtr == DEPTH - 2'd2) internal_full_n <= 1'b0; end end end assign shiftReg_addr = mOutPtr[ADDR_WIDTH] == 1'b0 ? mOutPtr[ADDR_WIDTH-1:0] : {ADDR_WIDTH{1'b0}}; assign shiftReg_ce = (if_write & if_write_ce) & internal_full_n; start_for_minus_vtde_shiftReg #( .DATA_WIDTH(DATA_WIDTH), .ADDR_WIDTH(ADDR_WIDTH), .DEPTH(DEPTH) ) U_start_for_minus_vtde_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule

7.106633