Datasets:
Sturges
/
AutoVCoder_round1

Dataset card Data Studio Files
xet
Community
1
code
stringlengths
35
6.69k
score
float64
6.5
11.5
module td_fused_top_fifo_w10_d8_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd10; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; sr_7 <= sr_6; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; 3'd7: q = sr_7; default: q = sr_7; endcase end endmodule
6.827284
module td_fused_top_fifo_w5_d8_S ( 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'd5; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w5_d8_S_shiftReg U_td_fused_top_fifo_w5_d8_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w5_d8_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd5; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; sr_7 <= sr_6; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; 3'd7: q = sr_7; default: q = sr_7; endcase end endmodule
6.827284
module td_fused_top_fifo_w7_d7_S ( 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'd7; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w7_d7_S_shiftReg U_td_fused_top_fifo_w7_d7_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w7_d7_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd7; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; default: q = sr_6; endcase end endmodule
6.827284
module td_fused_top_fifo_w7_d2_S_x ( 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'd7; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w7_d2_S_x_shiftReg U_td_fused_top_fifo_w7_d2_S_x_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w7_d2_S_x_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd7; 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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_Block_entry_proc_proc408 ( ap_clk, ap_rst, ap_start, ap_done, ap_continue, ap_idle, ap_ready, tmp, ap_return ); parameter ap_ST_fsm_state1 = 1'd1; input ap_clk; input ap_rst; input ap_start; output ap_done; input ap_continue; output ap_idle; output ap_ready; input [15:0] tmp; output [15:0] ap_return; reg ap_done; reg ap_idle; reg ap_ready; reg[15:0] ap_return; reg ap_done_reg; reg [0:0] ap_CS_fsm; wire ap_CS_fsm_state1; reg ap_block_state1; reg [15:0] ap_return_preg; reg [0:0] ap_NS_fsm; wire ap_ce_reg; // power-on initialization initial begin #0 ap_done_reg = 1'b0; #0 ap_CS_fsm = 1'd1; #0 ap_return_preg = 16'd0; end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_CS_fsm <= ap_ST_fsm_state1; end else begin ap_CS_fsm <= ap_NS_fsm; end end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_done_reg <= 1'b0; end else begin if ((ap_continue == 1'b1)) begin ap_done_reg <= 1'b0; end else if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_done_reg <= 1'b1; end end end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_return_preg <= 16'd0; end else begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_return_preg <= tmp; end end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_done = 1'b1; end else begin ap_done = ap_done_reg; end end always @(*) begin if (((ap_start == 1'b0) & (1'b1 == ap_CS_fsm_state1))) begin ap_idle = 1'b1; end else begin ap_idle = 1'b0; end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_ready = 1'b1; end else begin ap_ready = 1'b0; end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_return = tmp; end else begin ap_return = ap_return_preg; end end always @(*) begin case (ap_CS_fsm) ap_ST_fsm_state1: begin ap_NS_fsm = ap_ST_fsm_state1; end default: begin ap_NS_fsm = 'bx; end endcase end assign ap_CS_fsm_state1 = ap_CS_fsm[32'd0]; always @(*) begin ap_block_state1 = ((ap_start == 1'b0) | (ap_done_reg == 1'b1)); end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37738_accum1_out_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd8; parameter AddressWidth = 32'd3; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; td_fused_top_dataflow_in_loop_TOP_LOOP37738_accum1_out_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37738_accum1_out_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37738_accum1_out_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 3; parameter MEM_SIZE = 8; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37738_products_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, q1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd144; parameter AddressWidth = 32'd8; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; output [DataWidth - 1:0] q1; td_fused_top_dataflow_in_loop_TOP_LOOP37738_products_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37738_products_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .q1(q1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37738_products_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, q1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 8; parameter MEM_SIZE = 144; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; output reg [DWIDTH-1:0] q1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin q1 <= ram[addr1]; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37738_weight_vecs_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1, q1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd288; parameter AddressWidth = 32'd9; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; output [DataWidth - 1:0] q1; td_fused_top_dataflow_in_loop_TOP_LOOP37738_weight_vecs_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37738_weight_vecs_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1), .q1(q1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37738_weight_vecs_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, q1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 9; parameter MEM_SIZE = 288; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; output reg [DWIDTH-1:0] q1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; q1 <= ram[addr1]; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37738_ifmap_vec_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd144; parameter AddressWidth = 32'd8; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; td_fused_top_dataflow_in_loop_TOP_LOOP37738_ifmap_vec_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37738_ifmap_vec_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37738_ifmap_vec_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 8; parameter MEM_SIZE = 144; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; end end endmodule
6.827284
module td_fused_top_start_for_tdf4_readFilters36_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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_start_for_tdf4_readFilters36_U0_shiftReg U_td_fused_top_start_for_tdf4_readFilters36_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_start_for_tdf4_readFilters36_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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_fifo_w16_d2_S_x1 ( 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'd16; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w16_d2_S_x1_shiftReg U_td_fused_top_fifo_w16_d2_S_x1_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w16_d2_S_x1_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd16; 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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_fifo_w11_d2_S ( 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'd11; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w11_d2_S_shiftReg U_td_fused_top_fifo_w11_d2_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w11_d2_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd11; 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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_fifo_w12_d8_S_x ( 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'd12; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w12_d8_S_x_shiftReg U_td_fused_top_fifo_w12_d8_S_x_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w12_d8_S_x_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd12; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; sr_7 <= sr_6; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; 3'd7: q = sr_7; default: q = sr_7; endcase end endmodule
6.827284
module td_fused_top_fifo_w6_d8_S_x ( 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'd6; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w6_d8_S_x_shiftReg U_td_fused_top_fifo_w6_d8_S_x_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w6_d8_S_x_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd6; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; sr_7 <= sr_6; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; 3'd7: q = sr_7; default: q = sr_7; endcase end endmodule
6.827284
module td_fused_top_fifo_w1_d9_S_x ( 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'd9; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w1_d9_S_x_shiftReg U_td_fused_top_fifo_w1_d9_S_x_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w1_d9_S_x_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd9; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, sr_8; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; sr_7 <= sr_6; sr_8 <= sr_7; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, sr_8, a) begin case (a) 4'd0: q = sr_0; 4'd1: q = sr_1; 4'd2: q = sr_2; 4'd3: q = sr_3; 4'd4: q = sr_4; 4'd5: q = sr_5; 4'd6: q = sr_6; 4'd7: q = sr_7; 4'd8: q = sr_8; default: q = sr_8; endcase end endmodule
6.827284
module td_fused_top_fifo_w11_d7_S ( 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'd11; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w11_d7_S_shiftReg U_td_fused_top_fifo_w11_d7_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w11_d7_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd11; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; default: q = sr_6; endcase end endmodule
6.827284
module td_fused_top_fifo_w7_d2_S ( 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'd7; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w7_d2_S_shiftReg U_td_fused_top_fifo_w7_d2_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w7_d2_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd7; 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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_tdf4_l2_writeOutputs_133_running_sums_1 ( reset, clk, address0, ce0, we0, d0, address1, ce1, q1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd16; parameter AddressWidth = 32'd4; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; input [AddressWidth - 1:0] address1; input ce1; output [DataWidth - 1:0] q1; td_fused_top_tdf4_l2_writeOutputs_133_running_sums_1_ram td_fused_top_tdf4_l2_writeOutputs_133_running_sums_1_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .addr1(address1), .ce1(ce1), .q1(q1) ); endmodule
6.827284
module td_fused_top_tdf4_l2_writeOutputs_133_running_sums_1_ram ( addr0, ce0, d0, we0, addr1, ce1, q1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 4; parameter MEM_SIZE = 16; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; input [AWIDTH-1:0] addr1; input ce1; output reg [DWIDTH-1:0] q1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; //initial begin // $readmemh("./td_fused_top_tdf4_l2_writeOutputs_133_running_sums_1_ram.dat", ram); //end always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; end end always @(posedge clk) begin if (ce1) begin q1 <= ram[addr1]; end end endmodule
6.827284
module td_fused_top_Block_entry_proc_proc403 ( ap_clk, ap_rst, ap_start, ap_done, ap_continue, ap_idle, ap_ready, tmp, ap_return ); parameter ap_ST_fsm_state1 = 1'd1; input ap_clk; input ap_rst; input ap_start; output ap_done; input ap_continue; output ap_idle; output ap_ready; input [15:0] tmp; output [15:0] ap_return; reg ap_done; reg ap_idle; reg ap_ready; reg[15:0] ap_return; reg ap_done_reg; reg [0:0] ap_CS_fsm; wire ap_CS_fsm_state1; reg ap_block_state1; reg [15:0] ap_return_preg; reg [0:0] ap_NS_fsm; wire ap_ce_reg; // power-on initialization initial begin #0 ap_done_reg = 1'b0; #0 ap_CS_fsm = 1'd1; #0 ap_return_preg = 16'd0; end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_CS_fsm <= ap_ST_fsm_state1; end else begin ap_CS_fsm <= ap_NS_fsm; end end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_done_reg <= 1'b0; end else begin if ((ap_continue == 1'b1)) begin ap_done_reg <= 1'b0; end else if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_done_reg <= 1'b1; end end end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_return_preg <= 16'd0; end else begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_return_preg <= tmp; end end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_done = 1'b1; end else begin ap_done = ap_done_reg; end end always @(*) begin if (((ap_start == 1'b0) & (1'b1 == ap_CS_fsm_state1))) begin ap_idle = 1'b1; end else begin ap_idle = 1'b0; end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_ready = 1'b1; end else begin ap_ready = 1'b0; end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_return = tmp; end else begin ap_return = ap_return_preg; end end always @(*) begin case (ap_CS_fsm) ap_ST_fsm_state1: begin ap_NS_fsm = ap_ST_fsm_state1; end default: begin ap_NS_fsm = 'bx; end endcase end assign ap_CS_fsm_state1 = ap_CS_fsm[32'd0]; always @(*) begin ap_block_state1 = ((ap_start == 1'b0) | (ap_done_reg == 1'b1)); end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37832_l2_products #( parameter DataWidth = 16, AddressRange = 32, AddressWidth = 4, BufferCount = 2, IndexWidth = 1 ) ( // system signals input wire clk, input wire reset, // initiator input wire i_ce, input wire i_write, output wire i_full_n, input wire i_ce0, input wire i_we0, input wire [AddressWidth-1:0] i_address0, input wire [ DataWidth-1:0] i_d0, output wire [ DataWidth-1:0] i_q0, // target input wire t_ce, input wire t_read, output wire t_empty_n, input wire t_ce0, input wire t_we0, input wire [AddressWidth-1:0] t_address0, input wire [ DataWidth-1:0] t_d0, output wire [ DataWidth-1:0] t_q0 ); //------------------------Local signal------------------- // control/status reg [ IndexWidth-1:0] iptr = 1'b0; // initiator index reg [ IndexWidth-1:0] tptr = 1'b0; // target index reg [ IndexWidth:0] count = 1'b0; // count of written buffers reg full_n = 1'b1; // whether all buffers are written reg empty_n = 1'b0; // whether none of the buffers is written wire push_buf; // finish writing a buffer wire write_buf; // write a buffer wire pop_buf; // finish reading a buffer wire [AddressWidth+IndexWidth-1:0] memcore_iaddr; wire [AddressWidth+IndexWidth-1:0] memcore_taddr; //------------------------Instantiation------------------ assign memcore_iaddr = {i_address0, iptr}; assign memcore_taddr = {t_address0, tptr}; td_fused_top_dataflow_in_loop_TOP_LOOP37832_l2_products_memcore td_fused_top_dataflow_in_loop_TOP_LOOP37832_l2_products_memcore_U ( .reset (reset), .clk (clk), .address0(memcore_iaddr), .ce0 (i_ce0), .we0 (i_we0), .d0 (i_d0), .q0 (i_q0), .address1(memcore_taddr), .ce1 (t_ce0), .we1 (t_we0), .d1 (t_d0), .q1 (t_q0) ); //------------------------Body--------------------------- //++++++++++++++++++++++++output+++++++++++++++++++++++++ assign i_full_n = full_n; assign t_empty_n = empty_n; //+++++++++++++++++++++++++++++++++++++++++++++++++++++++ //++++++++++++++++++++++++control/status+++++++++++++++++ assign push_buf = i_ce & i_write & full_n; assign write_buf = i_ce & i_write; assign pop_buf = t_ce & t_read & empty_n; // iptr always @(posedge clk) begin if (reset == 1'b1) iptr <= 1'b0; else if (push_buf) begin if (iptr == BufferCount - 1'b1) iptr <= 1'b0; else iptr <= iptr + 1'b1; end end // tptr always @(posedge clk) begin if (reset == 1'b1) tptr <= 1'b0; else if (pop_buf) begin if (tptr == BufferCount - 1'b1) tptr <= 1'b0; else tptr <= tptr + 1'b1; end end // count always @(posedge clk) begin if (reset == 1'b1) count <= 1'b0; else if (push_buf && !pop_buf) count <= count + 1'b1; else if (!push_buf && pop_buf) count <= count - 1'b1; end // full_n always @(posedge clk) begin if (reset == 1'b1) full_n <= 1'b1; else if (push_buf && !pop_buf && count == BufferCount - 2'd2) full_n <= 1'b0; else if (!push_buf && pop_buf) full_n <= 1'b1; end // empty_n always @(posedge clk) begin if (reset == 1'b1) empty_n <= 1'b0; else if ((!write_buf && pop_buf && count == 1'b1) || (pop_buf && count == 1'b0)) empty_n <= 1'b0; else if (write_buf && !pop_buf) empty_n <= 1'b1; end //+++++++++++++++++++++++++++++++++++++++++++++++++++++++ endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37832_l2_products_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1, q1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd32; parameter AddressWidth = 32'd5; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; output [DataWidth - 1:0] q1; td_fused_top_dataflow_in_loop_TOP_LOOP37832_l2_products_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37832_l2_products_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1), .q1(q1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37832_l2_products_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, q1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 5; parameter MEM_SIZE = 32; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; output reg [DWIDTH-1:0] q1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; q1 <= ram[addr1]; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37832_accum1_out_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd8; parameter AddressWidth = 32'd3; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; td_fused_top_dataflow_in_loop_TOP_LOOP37832_accum1_out_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37832_accum1_out_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37832_accum1_out_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 3; parameter MEM_SIZE = 8; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37832_products_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, q1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd144; parameter AddressWidth = 32'd8; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; output [DataWidth - 1:0] q1; td_fused_top_dataflow_in_loop_TOP_LOOP37832_products_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37832_products_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .q1(q1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37832_products_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, q1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 8; parameter MEM_SIZE = 144; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; output reg [DWIDTH-1:0] q1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin q1 <= ram[addr1]; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37832_weight_vecs_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1, q1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd288; parameter AddressWidth = 32'd9; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; output [DataWidth - 1:0] q1; td_fused_top_dataflow_in_loop_TOP_LOOP37832_weight_vecs_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37832_weight_vecs_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1), .q1(q1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37832_weight_vecs_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, q1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 9; parameter MEM_SIZE = 288; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; output reg [DWIDTH-1:0] q1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; q1 <= ram[addr1]; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37832_ifmap_vec_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd144; parameter AddressWidth = 32'd8; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; td_fused_top_dataflow_in_loop_TOP_LOOP37832_ifmap_vec_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37832_ifmap_vec_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37832_ifmap_vec_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 8; parameter MEM_SIZE = 144; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; end end endmodule
6.827284
module td_fused_top_start_for_tdf3_readFilters30_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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_start_for_tdf3_readFilters30_U0_shiftReg U_td_fused_top_start_for_tdf3_readFilters30_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_start_for_tdf3_readFilters30_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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_fifo_w16_d2_S_x0 ( 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'd16; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w16_d2_S_x0_shiftReg U_td_fused_top_fifo_w16_d2_S_x0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w16_d2_S_x0_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd16; 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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_fifo_w12_d7_S ( 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'd12; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w12_d7_S_shiftReg U_td_fused_top_fifo_w12_d7_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w12_d7_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd12; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; default: q = sr_6; endcase end endmodule
6.827284
module td_fused_top_fifo_w6_d7_S ( 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'd6; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w6_d7_S_shiftReg U_td_fused_top_fifo_w6_d7_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w6_d7_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd6; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; default: q = sr_6; endcase end endmodule
6.827284
module td_fused_top_fifo_w4_d7_S ( 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'd4; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w4_d7_S_shiftReg U_td_fused_top_fifo_w4_d7_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w4_d7_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd4; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; default: q = sr_6; endcase end endmodule
6.827284
module td_fused_top_fifo_w4_d2_S_x ( 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'd4; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w4_d2_S_x_shiftReg U_td_fused_top_fifo_w4_d2_S_x_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w4_d2_S_x_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd4; 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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_Block_entry_proc_proc397 ( ap_clk, ap_rst, ap_start, ap_done, ap_continue, ap_idle, ap_ready, tmp, ap_return ); parameter ap_ST_fsm_state1 = 1'd1; input ap_clk; input ap_rst; input ap_start; output ap_done; input ap_continue; output ap_idle; output ap_ready; input [15:0] tmp; output [15:0] ap_return; reg ap_done; reg ap_idle; reg ap_ready; reg[15:0] ap_return; reg ap_done_reg; reg [0:0] ap_CS_fsm; wire ap_CS_fsm_state1; reg ap_block_state1; reg [15:0] ap_return_preg; reg [0:0] ap_NS_fsm; wire ap_ce_reg; // power-on initialization initial begin #0 ap_done_reg = 1'b0; #0 ap_CS_fsm = 1'd1; #0 ap_return_preg = 16'd0; end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_CS_fsm <= ap_ST_fsm_state1; end else begin ap_CS_fsm <= ap_NS_fsm; end end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_done_reg <= 1'b0; end else begin if ((ap_continue == 1'b1)) begin ap_done_reg <= 1'b0; end else if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_done_reg <= 1'b1; end end end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_return_preg <= 16'd0; end else begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_return_preg <= tmp; end end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_done = 1'b1; end else begin ap_done = ap_done_reg; end end always @(*) begin if (((ap_start == 1'b0) & (1'b1 == ap_CS_fsm_state1))) begin ap_idle = 1'b1; end else begin ap_idle = 1'b0; end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_ready = 1'b1; end else begin ap_ready = 1'b0; end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_return = tmp; end else begin ap_return = ap_return_preg; end end always @(*) begin case (ap_CS_fsm) ap_ST_fsm_state1: begin ap_NS_fsm = ap_ST_fsm_state1; end default: begin ap_NS_fsm = 'bx; end endcase end assign ap_CS_fsm_state1 = ap_CS_fsm[32'd0]; always @(*) begin ap_block_state1 = ((ap_start == 1'b0) | (ap_done_reg == 1'b1)); end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37928_accum1_out_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd8; parameter AddressWidth = 32'd3; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; td_fused_top_dataflow_in_loop_TOP_LOOP37928_accum1_out_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37928_accum1_out_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37928_accum1_out_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 3; parameter MEM_SIZE = 8; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37928_products_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, q1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd32; parameter AddressWidth = 32'd5; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; output [DataWidth - 1:0] q1; td_fused_top_dataflow_in_loop_TOP_LOOP37928_products_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37928_products_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .q1(q1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37928_products_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, q1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 5; parameter MEM_SIZE = 32; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; output reg [DWIDTH-1:0] q1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin q1 <= ram[addr1]; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37928_weight_vecs_0_0_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1, q1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd64; parameter AddressWidth = 32'd6; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; output [DataWidth - 1:0] q1; td_fused_top_dataflow_in_loop_TOP_LOOP37928_weight_vecs_0_0_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37928_weight_vecs_0_0_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1), .q1(q1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37928_weight_vecs_0_0_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, q1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 6; parameter MEM_SIZE = 64; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; output reg [DWIDTH-1:0] q1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; q1 <= ram[addr1]; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37928_ifmap_vec_0_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd32; parameter AddressWidth = 32'd5; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; td_fused_top_dataflow_in_loop_TOP_LOOP37928_ifmap_vec_0_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP37928_ifmap_vec_0_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP37928_ifmap_vec_0_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 5; parameter MEM_SIZE = 32; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; end end endmodule
6.827284
module td_fused_top_start_for_tdf2_readFilters24_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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_start_for_tdf2_readFilters24_U0_shiftReg U_td_fused_top_start_for_tdf2_readFilters24_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_start_for_tdf2_readFilters24_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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_fifo_w16_d2_S_x ( 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'd16; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w16_d2_S_x_shiftReg U_td_fused_top_fifo_w16_d2_S_x_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w16_d2_S_x_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd16; 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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_fifo_w1_d8_S ( 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w1_d8_S_shiftReg U_td_fused_top_fifo_w1_d8_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w1_d8_S_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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; sr_7 <= sr_6; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; 3'd7: q = sr_7; default: q = sr_7; endcase end endmodule
6.827284
module td_fused_top_fifo_w12_d8_S ( 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'd12; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w12_d8_S_shiftReg U_td_fused_top_fifo_w12_d8_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w12_d8_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd12; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; sr_7 <= sr_6; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; 3'd7: q = sr_7; default: q = sr_7; endcase end endmodule
6.827284
module td_fused_top_fifo_w6_d8_S ( 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'd6; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w6_d8_S_shiftReg U_td_fused_top_fifo_w6_d8_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w6_d8_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd6; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; sr_7 <= sr_6; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; 3'd7: q = sr_7; default: q = sr_7; endcase end endmodule
6.827284
module td_fused_top_fifo_w5_d7_S ( 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'd5; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w5_d7_S_shiftReg U_td_fused_top_fifo_w5_d7_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w5_d7_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd5; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, a) begin case (a) 3'd0: q = sr_0; 3'd1: q = sr_1; 3'd2: q = sr_2; 3'd3: q = sr_3; 3'd4: q = sr_4; 3'd5: q = sr_5; 3'd6: q = sr_6; default: q = sr_6; endcase end endmodule
6.827284
module td_fused_top_fifo_w5_d2_S ( 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'd5; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w5_d2_S_shiftReg U_td_fused_top_fifo_w5_d2_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w5_d2_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd5; 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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_Block_entry_proc_proc392 ( ap_clk, ap_rst, ap_start, ap_done, ap_continue, ap_idle, ap_ready, tmp, ap_return ); parameter ap_ST_fsm_state1 = 1'd1; input ap_clk; input ap_rst; input ap_start; output ap_done; input ap_continue; output ap_idle; output ap_ready; input [15:0] tmp; output [15:0] ap_return; reg ap_done; reg ap_idle; reg ap_ready; reg[15:0] ap_return; reg ap_done_reg; reg [0:0] ap_CS_fsm; wire ap_CS_fsm_state1; reg ap_block_state1; reg [15:0] ap_return_preg; reg [0:0] ap_NS_fsm; wire ap_ce_reg; // power-on initialization initial begin #0 ap_done_reg = 1'b0; #0 ap_CS_fsm = 1'd1; #0 ap_return_preg = 16'd0; end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_CS_fsm <= ap_ST_fsm_state1; end else begin ap_CS_fsm <= ap_NS_fsm; end end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_done_reg <= 1'b0; end else begin if ((ap_continue == 1'b1)) begin ap_done_reg <= 1'b0; end else if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_done_reg <= 1'b1; end end end always @(posedge ap_clk) begin if (ap_rst == 1'b1) begin ap_return_preg <= 16'd0; end else begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_return_preg <= tmp; end end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_done = 1'b1; end else begin ap_done = ap_done_reg; end end always @(*) begin if (((ap_start == 1'b0) & (1'b1 == ap_CS_fsm_state1))) begin ap_idle = 1'b1; end else begin ap_idle = 1'b0; end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_ready = 1'b1; end else begin ap_ready = 1'b0; end end always @(*) begin if ((~((ap_start == 1'b0) | (ap_done_reg == 1'b1)) & (1'b1 == ap_CS_fsm_state1))) begin ap_return = tmp; end else begin ap_return = ap_return_preg; end end always @(*) begin case (ap_CS_fsm) ap_ST_fsm_state1: begin ap_NS_fsm = ap_ST_fsm_state1; end default: begin ap_NS_fsm = 'bx; end endcase end assign ap_CS_fsm_state1 = ap_CS_fsm[32'd0]; always @(*) begin ap_block_state1 = ((ap_start == 1'b0) | (ap_done_reg == 1'b1)); end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP38022_accum1_out_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd8; parameter AddressWidth = 32'd3; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; td_fused_top_dataflow_in_loop_TOP_LOOP38022_accum1_out_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP38022_accum1_out_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP38022_accum1_out_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 3; parameter MEM_SIZE = 8; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP38022_products_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, q1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd144; parameter AddressWidth = 32'd8; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; output [DataWidth - 1:0] q1; td_fused_top_dataflow_in_loop_TOP_LOOP38022_products_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP38022_products_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .q1(q1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP38022_products_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, q1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 8; parameter MEM_SIZE = 144; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; output reg [DWIDTH-1:0] q1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin q1 <= ram[addr1]; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP38022_weight_vecs_0_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1, q1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd288; parameter AddressWidth = 32'd9; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; output [DataWidth - 1:0] q1; td_fused_top_dataflow_in_loop_TOP_LOOP38022_weight_vecs_0_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP38022_weight_vecs_0_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1), .q1(q1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP38022_weight_vecs_0_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, q1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 9; parameter MEM_SIZE = 288; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; output reg [DWIDTH-1:0] q1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; q1 <= ram[addr1]; end end endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP38022_ifmap_vec_memcore ( reset, clk, address0, ce0, we0, d0, q0, address1, ce1, we1, d1 ); parameter DataWidth = 32'd16; parameter AddressRange = 32'd144; parameter AddressWidth = 32'd8; input reset; input clk; input [AddressWidth - 1:0] address0; input ce0; input we0; input [DataWidth - 1:0] d0; output [DataWidth - 1:0] q0; input [AddressWidth - 1:0] address1; input ce1; input we1; input [DataWidth - 1:0] d1; td_fused_top_dataflow_in_loop_TOP_LOOP38022_ifmap_vec_memcore_ram td_fused_top_dataflow_in_loop_TOP_LOOP38022_ifmap_vec_memcore_ram_U( .clk(clk), .addr0(address0), .ce0(ce0), .we0(we0), .d0(d0), .q0(q0), .addr1(address1), .ce1(ce1), .we1(we1), .d1(d1) ); endmodule
6.827284
module td_fused_top_dataflow_in_loop_TOP_LOOP38022_ifmap_vec_memcore_ram ( addr0, ce0, d0, we0, q0, addr1, ce1, d1, we1, clk ); parameter DWIDTH = 16; parameter AWIDTH = 8; parameter MEM_SIZE = 144; input [AWIDTH-1:0] addr0; input ce0; input [DWIDTH-1:0] d0; input we0; output reg [DWIDTH-1:0] q0; input [AWIDTH-1:0] addr1; input ce1; input [DWIDTH-1:0] d1; input we1; input clk; reg [DWIDTH-1:0] ram[MEM_SIZE-1:0]; always @(posedge clk) begin if (ce0) begin if (we0) ram[addr0] <= d0; q0 <= ram[addr0]; end end always @(posedge clk) begin if (ce1) begin if (we1) ram[addr1] <= d1; end end endmodule
6.827284
module td_fused_top_start_for_tdf1_readFilters18_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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_start_for_tdf1_readFilters18_U0_shiftReg U_td_fused_top_start_for_tdf1_readFilters18_U0_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_start_for_tdf1_readFilters18_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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_fifo_w16_d2_S ( 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'd16; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w16_d2_S_shiftReg U_td_fused_top_fifo_w16_d2_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w16_d2_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd16; 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] sr_0, sr_1; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; end end always @(sr_0, sr_1, a) begin case (a) 1'd0: q = sr_0; 1'd1: q = sr_1; default: q = sr_1; endcase end endmodule
6.827284
module td_fused_top_fifo_w1_d9_S ( 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'd9; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w1_d9_S_shiftReg U_td_fused_top_fifo_w1_d9_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w1_d9_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd1; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd9; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, sr_8; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; sr_7 <= sr_6; sr_8 <= sr_7; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, sr_8, a) begin case (a) 4'd0: q = sr_0; 4'd1: q = sr_1; 4'd2: q = sr_2; 4'd3: q = sr_3; 4'd4: q = sr_4; 4'd5: q = sr_5; 4'd6: q = sr_6; 4'd7: q = sr_7; 4'd8: q = sr_8; default: q = sr_8; endcase end endmodule
6.827284
module td_fused_top_fifo_w14_d9_S ( 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'd14; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd9; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w14_d9_S_shiftReg U_td_fused_top_fifo_w14_d9_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w14_d9_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd14; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd9; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, sr_8; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; sr_7 <= sr_6; sr_8 <= sr_7; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, sr_8, a) begin case (a) 4'd0: q = sr_0; 4'd1: q = sr_1; 4'd2: q = sr_2; 4'd3: q = sr_3; 4'd4: q = sr_4; 4'd5: q = sr_5; 4'd6: q = sr_6; 4'd7: q = sr_7; 4'd8: q = sr_8; default: q = sr_8; endcase end endmodule
6.827284
module td_fused_top_fifo_w7_d9_S ( 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'd7; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd9; 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; reg internal_full_n = 1; assign if_full_n = internal_full_n; assign if_empty_n = internal_empty_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; td_fused_top_fifo_w7_d9_S_shiftReg U_td_fused_top_fifo_w7_d9_S_ram ( .clk(clk), .data(shiftReg_data), .ce(shiftReg_ce), .a(shiftReg_addr), .q(shiftReg_q) ); endmodule
6.827284
module td_fused_top_fifo_w7_d9_S_shiftReg ( clk, data, ce, a, q ); parameter DATA_WIDTH = 32'd7; parameter ADDR_WIDTH = 32'd4; parameter DEPTH = 5'd9; 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] sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, sr_8; integer i; always @(posedge clk) begin if (ce) begin sr_0 <= data; sr_1 <= sr_0; sr_2 <= sr_1; sr_3 <= sr_2; sr_4 <= sr_3; sr_5 <= sr_4; sr_6 <= sr_5; sr_7 <= sr_6; sr_8 <= sr_7; end end always @(sr_0, sr_1, sr_2, sr_3, sr_4, sr_5, sr_6, sr_7, sr_8, a) begin case (a) 4'd0: q = sr_0; 4'd1: q = sr_1; 4'd2: q = sr_2; 4'd3: q = sr_3; 4'd4: q = sr_4; 4'd5: q = sr_5; 4'd6: q = sr_6; 4'd7: q = sr_7; 4'd8: q = sr_8; default: q = sr_8; endcase end endmodule
6.827284