// ================================================================
// NVDLA Open Source Project
//
// Copyright(c) 2016 - 2017 NVIDIA Corporation. Licensed under the
// NVDLA Open Hardware License; Check "LICENSE" which comes with
// this distribution for more information.
// ================================================================
// File Name: NV_NVDLA_PDP_reg.v
`include "simulate_x_tick.vh"
module NV_NVDLA_PDP_reg (
nvdla_core_clk //|< i
,nvdla_core_rstn //|< i
,csb2pdp_req_pd //|< i
,csb2pdp_req_pvld //|< i
,dp2reg_d0_perf_write_stall //|< i
,dp2reg_d1_perf_write_stall //|< i
,dp2reg_done //|< i
,dp2reg_inf_input_num //|< i
,dp2reg_nan_input_num //|< i
,dp2reg_nan_output_num //|< i
,csb2pdp_req_prdy //|> o
,pdp2csb_resp_pd //|> o
,pdp2csb_resp_valid //|> o
,reg2dp_cube_in_channel //|> o
,reg2dp_cube_in_height //|> o
,reg2dp_cube_in_width //|> o
,reg2dp_cube_out_channel //|> o
,reg2dp_cube_out_height //|> o
,reg2dp_cube_out_width //|> o
,reg2dp_cya //|> o
,reg2dp_dma_en //|> o
,reg2dp_dst_base_addr_high //|> o
,reg2dp_dst_base_addr_low //|> o
,reg2dp_dst_line_stride //|> o
,reg2dp_dst_ram_type //|> o
,reg2dp_dst_surface_stride //|> o
,reg2dp_flying_mode //|> o
,reg2dp_input_data //|> o
,reg2dp_interrupt_ptr //|> o
,reg2dp_kernel_height //|> o
,reg2dp_kernel_stride_height //|> o
,reg2dp_kernel_stride_width //|> o
,reg2dp_kernel_width //|> o
,reg2dp_nan_to_zero //|> o
,reg2dp_op_en //|> o
,reg2dp_pad_bottom //|> o
,reg2dp_pad_left //|> o
,reg2dp_pad_right //|> o
,reg2dp_pad_top //|> o
,reg2dp_pad_value_1x //|> o
,reg2dp_pad_value_2x //|> o
,reg2dp_pad_value_3x //|> o
,reg2dp_pad_value_4x //|> o
,reg2dp_pad_value_5x //|> o
,reg2dp_pad_value_6x //|> o
,reg2dp_pad_value_7x //|> o
,reg2dp_partial_width_in_first //|> o
,reg2dp_partial_width_in_last //|> o
,reg2dp_partial_width_in_mid //|> o
,reg2dp_partial_width_out_first //|> o
,reg2dp_partial_width_out_last //|> o
,reg2dp_partial_width_out_mid //|> o
,reg2dp_pooling_method //|> o
,reg2dp_recip_kernel_height //|> o
,reg2dp_recip_kernel_width //|> o
,reg2dp_split_num //|> o
,reg2dp_src_base_addr_high //|> o
,reg2dp_src_base_addr_low //|> o
,reg2dp_src_line_stride //|> o
,reg2dp_src_surface_stride //|> o
,slcg_op_en //|> o
);
input nvdla_core_clk;
input nvdla_core_rstn;
input [62:0] csb2pdp_req_pd;
input csb2pdp_req_pvld;
input [31:0] dp2reg_d0_perf_write_stall;
input [31:0] dp2reg_d1_perf_write_stall;
input dp2reg_done;
input [31:0] dp2reg_inf_input_num;
input [31:0] dp2reg_nan_input_num;
input [31:0] dp2reg_nan_output_num;
output csb2pdp_req_prdy;
output [33:0] pdp2csb_resp_pd;
output pdp2csb_resp_valid;
output [12:0] reg2dp_cube_in_channel;
output [12:0] reg2dp_cube_in_height;
output [12:0] reg2dp_cube_in_width;
output [12:0] reg2dp_cube_out_channel;
output [12:0] reg2dp_cube_out_height;
output [12:0] reg2dp_cube_out_width;
output [31:0] reg2dp_cya;
output reg2dp_dma_en;
output [31:0] reg2dp_dst_base_addr_high;
output [31:0] reg2dp_dst_base_addr_low;
output [31:0] reg2dp_dst_line_stride;
output reg2dp_dst_ram_type;
output [31:0] reg2dp_dst_surface_stride;
output reg2dp_flying_mode;
output [1:0] reg2dp_input_data;
output reg2dp_interrupt_ptr;
output [3:0] reg2dp_kernel_height;
output [3:0] reg2dp_kernel_stride_height;
output [3:0] reg2dp_kernel_stride_width;
output [3:0] reg2dp_kernel_width;
output reg2dp_nan_to_zero;
output reg2dp_op_en;
output [2:0] reg2dp_pad_bottom;
output [2:0] reg2dp_pad_left;
output [2:0] reg2dp_pad_right;
output [2:0] reg2dp_pad_top;
output [18:0] reg2dp_pad_value_1x;
output [18:0] reg2dp_pad_value_2x;
output [18:0] reg2dp_pad_value_3x;
output [18:0] reg2dp_pad_value_4x;
output [18:0] reg2dp_pad_value_5x;
output [18:0] reg2dp_pad_value_6x;
output [18:0] reg2dp_pad_value_7x;
output [9:0] reg2dp_partial_width_in_first;
output [9:0] reg2dp_partial_width_in_last;
output [9:0] reg2dp_partial_width_in_mid;
output [9:0] reg2dp_partial_width_out_first;
output [9:0] reg2dp_partial_width_out_last;
output [9:0] reg2dp_partial_width_out_mid;
output [1:0] reg2dp_pooling_method;
output [16:0] reg2dp_recip_kernel_height;
output [16:0] reg2dp_recip_kernel_width;
output [7:0] reg2dp_split_num;
output [31:0] reg2dp_src_base_addr_high;
output [31:0] reg2dp_src_base_addr_low;
output [31:0] reg2dp_src_line_stride;
output [31:0] reg2dp_src_surface_stride;
output [2:0] slcg_op_en;
wire csb_rresp_error;
wire [33:0] csb_rresp_pd_w;
wire [31:0] csb_rresp_rdat;
wire csb_wresp_error;
wire [33:0] csb_wresp_pd_w;
wire [31:0] csb_wresp_rdat;
wire [23:0] d0_reg_offset;
wire [31:0] d0_reg_rd_data;
wire [31:0] d0_reg_wr_data;
wire d0_reg_wr_en;
wire [23:0] d1_reg_offset;
wire [31:0] d1_reg_rd_data;
wire [31:0] d1_reg_wr_data;
wire d1_reg_wr_en;
wire dp2reg_consumer_w;
wire [12:0] reg2dp_d0_cube_in_channel;
wire [12:0] reg2dp_d0_cube_in_height;
wire [12:0] reg2dp_d0_cube_in_width;
wire [12:0] reg2dp_d0_cube_out_channel;
wire [12:0] reg2dp_d0_cube_out_height;
wire [12:0] reg2dp_d0_cube_out_width;
wire [31:0] reg2dp_d0_cya;
wire reg2dp_d0_dma_en;
wire [31:0] reg2dp_d0_dst_base_addr_high;
wire [31:0] reg2dp_d0_dst_base_addr_low;
wire [31:0] reg2dp_d0_dst_line_stride;
wire reg2dp_d0_dst_ram_type;
wire [31:0] reg2dp_d0_dst_surface_stride;
wire reg2dp_d0_flying_mode;
wire [1:0] reg2dp_d0_input_data;
wire [3:0] reg2dp_d0_kernel_height;
wire [3:0] reg2dp_d0_kernel_stride_height;
wire [3:0] reg2dp_d0_kernel_stride_width;
wire [3:0] reg2dp_d0_kernel_width;
wire reg2dp_d0_nan_to_zero;
wire reg2dp_d0_op_en_trigger;
wire [2:0] reg2dp_d0_pad_bottom;
wire [2:0] reg2dp_d0_pad_left;
wire [2:0] reg2dp_d0_pad_right;
wire [2:0] reg2dp_d0_pad_top;
wire [18:0] reg2dp_d0_pad_value_1x;
wire [18:0] reg2dp_d0_pad_value_2x;
wire [18:0] reg2dp_d0_pad_value_3x;
wire [18:0] reg2dp_d0_pad_value_4x;
wire [18:0] reg2dp_d0_pad_value_5x;
wire [18:0] reg2dp_d0_pad_value_6x;
wire [18:0] reg2dp_d0_pad_value_7x;
wire [9:0] reg2dp_d0_partial_width_in_first;
wire [9:0] reg2dp_d0_partial_width_in_last;
wire [9:0] reg2dp_d0_partial_width_in_mid;
wire [9:0] reg2dp_d0_partial_width_out_first;
wire [9:0] reg2dp_d0_partial_width_out_last;
wire [9:0] reg2dp_d0_partial_width_out_mid;
wire [1:0] reg2dp_d0_pooling_method;
wire [16:0] reg2dp_d0_recip_kernel_height;
wire [16:0] reg2dp_d0_recip_kernel_width;
wire [7:0] reg2dp_d0_split_num;
wire [31:0] reg2dp_d0_src_base_addr_high;
wire [31:0] reg2dp_d0_src_base_addr_low;
wire [31:0] reg2dp_d0_src_line_stride;
wire [31:0] reg2dp_d0_src_surface_stride;
wire [12:0] reg2dp_d1_cube_in_channel;
wire [12:0] reg2dp_d1_cube_in_height;
wire [12:0] reg2dp_d1_cube_in_width;
wire [12:0] reg2dp_d1_cube_out_channel;
wire [12:0] reg2dp_d1_cube_out_height;
wire [12:0] reg2dp_d1_cube_out_width;
wire [31:0] reg2dp_d1_cya;
wire reg2dp_d1_dma_en;
wire [31:0] reg2dp_d1_dst_base_addr_high;
wire [31:0] reg2dp_d1_dst_base_addr_low;
wire [31:0] reg2dp_d1_dst_line_stride;
wire reg2dp_d1_dst_ram_type;
wire [31:0] reg2dp_d1_dst_surface_stride;
wire reg2dp_d1_flying_mode;
wire [1:0] reg2dp_d1_input_data;
wire [3:0] reg2dp_d1_kernel_height;
wire [3:0] reg2dp_d1_kernel_stride_height;
wire [3:0] reg2dp_d1_kernel_stride_width;
wire [3:0] reg2dp_d1_kernel_width;
wire reg2dp_d1_nan_to_zero;
wire reg2dp_d1_op_en_trigger;
wire [2:0] reg2dp_d1_pad_bottom;
wire [2:0] reg2dp_d1_pad_left;
wire [2:0] reg2dp_d1_pad_right;
wire [2:0] reg2dp_d1_pad_top;
wire [18:0] reg2dp_d1_pad_value_1x;
wire [18:0] reg2dp_d1_pad_value_2x;
wire [18:0] reg2dp_d1_pad_value_3x;
wire [18:0] reg2dp_d1_pad_value_4x;
wire [18:0] reg2dp_d1_pad_value_5x;
wire [18:0] reg2dp_d1_pad_value_6x;
wire [18:0] reg2dp_d1_pad_value_7x;
wire [9:0] reg2dp_d1_partial_width_in_first;
wire [9:0] reg2dp_d1_partial_width_in_last;
wire [9:0] reg2dp_d1_partial_width_in_mid;
wire [9:0] reg2dp_d1_partial_width_out_first;
wire [9:0] reg2dp_d1_partial_width_out_last;
wire [9:0] reg2dp_d1_partial_width_out_mid;
wire [1:0] reg2dp_d1_pooling_method;
wire [16:0] reg2dp_d1_recip_kernel_height;
wire [16:0] reg2dp_d1_recip_kernel_width;
wire [7:0] reg2dp_d1_split_num;
wire [31:0] reg2dp_d1_src_base_addr_high;
wire [31:0] reg2dp_d1_src_base_addr_low;
wire [31:0] reg2dp_d1_src_line_stride;
wire [31:0] reg2dp_d1_src_surface_stride;
wire [2:0] reg2dp_op_en_reg_w;
wire reg2dp_producer;
wire [23:0] reg_offset;
wire [31:0] reg_rd_data;
wire reg_rd_en;
wire [31:0] reg_wr_data;
wire reg_wr_en;
wire [21:0] req_addr;
wire [1:0] req_level;
wire req_nposted;
wire req_srcpriv;
wire [31:0] req_wdat;
wire [3:0] req_wrbe;
wire req_write;
wire [23:0] s_reg_offset;
wire [31:0] s_reg_rd_data;
wire [31:0] s_reg_wr_data;
wire s_reg_wr_en;
wire select_d0;
wire select_d1;
wire select_s;
wire [2:0] slcg_op_en_d0;
reg dp2reg_consumer;
reg dp2reg_d0_clr;
reg [31:0] dp2reg_d0_inf_input_num;
reg [31:0] dp2reg_d0_inf_input_num_w;
reg [31:0] dp2reg_d0_nan_input_num;
reg [31:0] dp2reg_d0_nan_input_num_w;
reg [31:0] dp2reg_d0_nan_output_num;
reg [31:0] dp2reg_d0_nan_output_num_w;
reg dp2reg_d0_reg;
reg dp2reg_d0_set;
reg dp2reg_d1_clr;
reg [31:0] dp2reg_d1_inf_input_num;
reg [31:0] dp2reg_d1_inf_input_num_w;
reg [31:0] dp2reg_d1_nan_input_num;
reg [31:0] dp2reg_d1_nan_input_num_w;
reg [31:0] dp2reg_d1_nan_output_num;
reg [31:0] dp2reg_d1_nan_output_num_w;
reg dp2reg_d1_reg;
reg dp2reg_d1_set;
reg [1:0] dp2reg_status_0;
reg [1:0] dp2reg_status_1;
reg [33:0] pdp2csb_resp_pd;
reg pdp2csb_resp_valid;
reg [12:0] reg2dp_cube_in_channel;
reg [12:0] reg2dp_cube_in_height;
reg [12:0] reg2dp_cube_in_width;
reg [12:0] reg2dp_cube_out_channel;
reg [12:0] reg2dp_cube_out_height;
reg [12:0] reg2dp_cube_out_width;
reg [31:0] reg2dp_cya;
reg reg2dp_d0_op_en;
reg reg2dp_d0_op_en_w;
reg reg2dp_d1_op_en;
reg reg2dp_d1_op_en_w;
reg reg2dp_dma_en;
reg [31:0] reg2dp_dst_base_addr_high;
reg [31:0] reg2dp_dst_base_addr_low;
reg [31:0] reg2dp_dst_line_stride;
reg reg2dp_dst_ram_type;
reg [31:0] reg2dp_dst_surface_stride;
reg reg2dp_flying_mode;
reg [1:0] reg2dp_input_data;
reg [3:0] reg2dp_kernel_height;
reg [3:0] reg2dp_kernel_stride_height;
reg [3:0] reg2dp_kernel_stride_width;
reg [3:0] reg2dp_kernel_width;
reg reg2dp_nan_to_zero;
reg reg2dp_op_en_ori;
reg [2:0] reg2dp_op_en_reg;
reg [2:0] reg2dp_pad_bottom;
reg [2:0] reg2dp_pad_left;
reg [2:0] reg2dp_pad_right;
reg [2:0] reg2dp_pad_top;
reg [18:0] reg2dp_pad_value_1x;
reg [18:0] reg2dp_pad_value_2x;
reg [18:0] reg2dp_pad_value_3x;
reg [18:0] reg2dp_pad_value_4x;
reg [18:0] reg2dp_pad_value_5x;
reg [18:0] reg2dp_pad_value_6x;
reg [18:0] reg2dp_pad_value_7x;
reg [9:0] reg2dp_partial_width_in_first;
reg [9:0] reg2dp_partial_width_in_last;
reg [9:0] reg2dp_partial_width_in_mid;
reg [9:0] reg2dp_partial_width_out_first;
reg [9:0] reg2dp_partial_width_out_last;
reg [9:0] reg2dp_partial_width_out_mid;
reg [1:0] reg2dp_pooling_method;
reg [16:0] reg2dp_recip_kernel_height;
reg [16:0] reg2dp_recip_kernel_width;
reg [7:0] reg2dp_split_num;
reg [31:0] reg2dp_src_base_addr_high;
reg [31:0] reg2dp_src_base_addr_low;
reg [31:0] reg2dp_src_line_stride;
reg [31:0] reg2dp_src_surface_stride;
reg [62:0] req_pd;
reg req_pvld;
reg [2:0] slcg_op_en_d1;
reg [2:0] slcg_op_en_d2;
reg [2:0] slcg_op_en_d3;
//Instance single register group
NV_NVDLA_PDP_REG_single u_single_reg (
.reg_rd_data (s_reg_rd_data[31:0]) //|> w
,.reg_offset (s_reg_offset[11:0]) //|< w
,.reg_wr_data (s_reg_wr_data[31:0]) //|< w
,.reg_wr_en (s_reg_wr_en) //|< w
,.nvdla_core_clk (nvdla_core_clk) //|< i
,.nvdla_core_rstn (nvdla_core_rstn) //|< i
,.producer (reg2dp_producer) //|> w
,.consumer (dp2reg_consumer) //|< r
,.status_0 (dp2reg_status_0[1:0]) //|< r
,.status_1 (dp2reg_status_1[1:0]) //|< r
);
//Instance two duplicated register groups
NV_NVDLA_PDP_REG_dual u_dual_reg_d0 (
.reg_rd_data (d0_reg_rd_data[31:0]) //|> w
,.reg_offset (d0_reg_offset[11:0]) //|< w
,.reg_wr_data (d0_reg_wr_data[31:0]) //|< w
,.reg_wr_en (d0_reg_wr_en) //|< w
,.nvdla_core_clk (nvdla_core_clk) //|< i
,.nvdla_core_rstn (nvdla_core_rstn) //|< i
,.cya (reg2dp_d0_cya[31:0]) //|> w
,.cube_in_channel (reg2dp_d0_cube_in_channel[12:0]) //|> w
,.cube_in_height (reg2dp_d0_cube_in_height[12:0]) //|> w
,.cube_in_width (reg2dp_d0_cube_in_width[12:0]) //|> w
,.cube_out_channel (reg2dp_d0_cube_out_channel[12:0]) //|> w
,.cube_out_height (reg2dp_d0_cube_out_height[12:0]) //|> w
,.cube_out_width (reg2dp_d0_cube_out_width[12:0]) //|> w
,.input_data (reg2dp_d0_input_data[1:0]) //|> w
,.dst_base_addr_high (reg2dp_d0_dst_base_addr_high[31:0]) //|> w
,.dst_base_addr_low (reg2dp_d0_dst_base_addr_low[31:0]) //|> w
,.dst_line_stride (reg2dp_d0_dst_line_stride[31:0]) //|> w
,.dst_ram_type (reg2dp_d0_dst_ram_type) //|> w
,.dst_surface_stride (reg2dp_d0_dst_surface_stride[31:0]) //|> w
,.nan_to_zero (reg2dp_d0_nan_to_zero) //|> w
,.flying_mode (reg2dp_d0_flying_mode) //|> w
,.pooling_method (reg2dp_d0_pooling_method[1:0]) //|> w
,.split_num (reg2dp_d0_split_num[7:0]) //|> w
,.op_en_trigger (reg2dp_d0_op_en_trigger) //|> w
,.partial_width_in_first (reg2dp_d0_partial_width_in_first[9:0]) //|> w
,.partial_width_in_last (reg2dp_d0_partial_width_in_last[9:0]) //|> w
,.partial_width_in_mid (reg2dp_d0_partial_width_in_mid[9:0]) //|> w
,.partial_width_out_first (reg2dp_d0_partial_width_out_first[9:0]) //|> w
,.partial_width_out_last (reg2dp_d0_partial_width_out_last[9:0]) //|> w
,.partial_width_out_mid (reg2dp_d0_partial_width_out_mid[9:0]) //|> w
,.dma_en (reg2dp_d0_dma_en) //|> w
,.kernel_height (reg2dp_d0_kernel_height[3:0]) //|> w
,.kernel_stride_height (reg2dp_d0_kernel_stride_height[3:0]) //|> w
,.kernel_stride_width (reg2dp_d0_kernel_stride_width[3:0]) //|> w
,.kernel_width (reg2dp_d0_kernel_width[3:0]) //|> w
,.pad_bottom (reg2dp_d0_pad_bottom[2:0]) //|> w
,.pad_left (reg2dp_d0_pad_left[2:0]) //|> w
,.pad_right (reg2dp_d0_pad_right[2:0]) //|> w
,.pad_top (reg2dp_d0_pad_top[2:0]) //|> w
,.pad_value_1x (reg2dp_d0_pad_value_1x[18:0]) //|> w
,.pad_value_2x (reg2dp_d0_pad_value_2x[18:0]) //|> w
,.pad_value_3x (reg2dp_d0_pad_value_3x[18:0]) //|> w
,.pad_value_4x (reg2dp_d0_pad_value_4x[18:0]) //|> w
,.pad_value_5x (reg2dp_d0_pad_value_5x[18:0]) //|> w
,.pad_value_6x (reg2dp_d0_pad_value_6x[18:0]) //|> w
,.pad_value_7x (reg2dp_d0_pad_value_7x[18:0]) //|> w
,.recip_kernel_height (reg2dp_d0_recip_kernel_height[16:0]) //|> w
,.recip_kernel_width (reg2dp_d0_recip_kernel_width[16:0]) //|> w
,.src_base_addr_high (reg2dp_d0_src_base_addr_high[31:0]) //|> w
,.src_base_addr_low (reg2dp_d0_src_base_addr_low[31:0]) //|> w
,.src_line_stride (reg2dp_d0_src_line_stride[31:0]) //|> w
,.src_surface_stride (reg2dp_d0_src_surface_stride[31:0]) //|> w
,.inf_input_num (dp2reg_d0_inf_input_num[31:0]) //|< r
,.nan_input_num (dp2reg_d0_nan_input_num[31:0]) //|< r
,.nan_output_num (dp2reg_d0_nan_output_num[31:0]) //|< r
,.op_en (reg2dp_d0_op_en) //|< r
,.perf_write_stall (dp2reg_d0_perf_write_stall[31:0]) //|< i
);
NV_NVDLA_PDP_REG_dual u_dual_reg_d1 (
.reg_rd_data (d1_reg_rd_data[31:0]) //|> w
,.reg_offset (d1_reg_offset[11:0]) //|< w
,.reg_wr_data (d1_reg_wr_data[31:0]) //|< w
,.reg_wr_en (d1_reg_wr_en) //|< w
,.nvdla_core_clk (nvdla_core_clk) //|< i
,.nvdla_core_rstn (nvdla_core_rstn) //|< i
,.cya (reg2dp_d1_cya[31:0]) //|> w
,.cube_in_channel (reg2dp_d1_cube_in_channel[12:0]) //|> w
,.cube_in_height (reg2dp_d1_cube_in_height[12:0]) //|> w
,.cube_in_width (reg2dp_d1_cube_in_width[12:0]) //|> w
,.cube_out_channel (reg2dp_d1_cube_out_channel[12:0]) //|> w
,.cube_out_height (reg2dp_d1_cube_out_height[12:0]) //|> w
,.cube_out_width (reg2dp_d1_cube_out_width[12:0]) //|> w
,.input_data (reg2dp_d1_input_data[1:0]) //|> w
,.dst_base_addr_high (reg2dp_d1_dst_base_addr_high[31:0]) //|> w
,.dst_base_addr_low (reg2dp_d1_dst_base_addr_low[31:0]) //|> w
,.dst_line_stride (reg2dp_d1_dst_line_stride[31:0]) //|> w
,.dst_ram_type (reg2dp_d1_dst_ram_type) //|> w
,.dst_surface_stride (reg2dp_d1_dst_surface_stride[31:0]) //|> w
,.nan_to_zero (reg2dp_d1_nan_to_zero) //|> w
,.flying_mode (reg2dp_d1_flying_mode) //|> w
,.pooling_method (reg2dp_d1_pooling_method[1:0]) //|> w
,.split_num (reg2dp_d1_split_num[7:0]) //|> w
,.op_en_trigger (reg2dp_d1_op_en_trigger) //|> w
,.partial_width_in_first (reg2dp_d1_partial_width_in_first[9:0]) //|> w
,.partial_width_in_last (reg2dp_d1_partial_width_in_last[9:0]) //|> w
,.partial_width_in_mid (reg2dp_d1_partial_width_in_mid[9:0]) //|> w
,.partial_width_out_first (reg2dp_d1_partial_width_out_first[9:0]) //|> w
,.partial_width_out_last (reg2dp_d1_partial_width_out_last[9:0]) //|> w
,.partial_width_out_mid (reg2dp_d1_partial_width_out_mid[9:0]) //|> w
,.dma_en (reg2dp_d1_dma_en) //|> w
,.kernel_height (reg2dp_d1_kernel_height[3:0]) //|> w
,.kernel_stride_height (reg2dp_d1_kernel_stride_height[3:0]) //|> w
,.kernel_stride_width (reg2dp_d1_kernel_stride_width[3:0]) //|> w
,.kernel_width (reg2dp_d1_kernel_width[3:0]) //|> w
,.pad_bottom (reg2dp_d1_pad_bottom[2:0]) //|> w
,.pad_left (reg2dp_d1_pad_left[2:0]) //|> w
,.pad_right (reg2dp_d1_pad_right[2:0]) //|> w
,.pad_top (reg2dp_d1_pad_top[2:0]) //|> w
,.pad_value_1x (reg2dp_d1_pad_value_1x[18:0]) //|> w
,.pad_value_2x (reg2dp_d1_pad_value_2x[18:0]) //|> w
,.pad_value_3x (reg2dp_d1_pad_value_3x[18:0]) //|> w
,.pad_value_4x (reg2dp_d1_pad_value_4x[18:0]) //|> w
,.pad_value_5x (reg2dp_d1_pad_value_5x[18:0]) //|> w
,.pad_value_6x (reg2dp_d1_pad_value_6x[18:0]) //|> w
,.pad_value_7x (reg2dp_d1_pad_value_7x[18:0]) //|> w
,.recip_kernel_height (reg2dp_d1_recip_kernel_height[16:0]) //|> w
,.recip_kernel_width (reg2dp_d1_recip_kernel_width[16:0]) //|> w
,.src_base_addr_high (reg2dp_d1_src_base_addr_high[31:0]) //|> w
,.src_base_addr_low (reg2dp_d1_src_base_addr_low[31:0]) //|> w
,.src_line_stride (reg2dp_d1_src_line_stride[31:0]) //|> w
,.src_surface_stride (reg2dp_d1_src_surface_stride[31:0]) //|> w
,.inf_input_num (dp2reg_d1_inf_input_num[31:0]) //|< r
,.nan_input_num (dp2reg_d1_nan_input_num[31:0]) //|< r
,.nan_output_num (dp2reg_d1_nan_output_num[31:0]) //|< r
,.op_en (reg2dp_d1_op_en) //|< r
,.perf_write_stall (dp2reg_d1_perf_write_stall[31:0]) //|< i
);
////////////////////////////////////////////////////////////////////////
// //
// GENERATE CONSUMER PIONTER IN GENERAL SINGLE REGISTER GROUP //
// //
////////////////////////////////////////////////////////////////////////
assign dp2reg_consumer_w = ~dp2reg_consumer;
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
dp2reg_consumer <= 1'b0;
end else begin
if ((dp2reg_done) == 1'b1) begin
dp2reg_consumer <= dp2reg_consumer_w;
// VCS coverage off
end else if ((dp2reg_done) == 1'b0) begin
end else begin
dp2reg_consumer <= 'bx; // spyglass disable STARC-2.10.1.6 W443 NoWidthInBasedNum-ML -- (Constant containing x or z used, Based number `bx contains an X, Width specification missing for based number)
// VCS coverage on
end
end
end
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass disable_block NoWidthInBasedNum-ML
// spyglass disable_block STARC-2.10.3.2a
// spyglass disable_block STARC05-2.1.3.1
// spyglass disable_block STARC-2.1.4.6
// spyglass disable_block W116
// spyglass disable_block W154
// spyglass disable_block W239
// spyglass disable_block W362
// spyglass disable_block WRN_58
// spyglass disable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
`ifdef ASSERT_ON
`ifdef FV_ASSERT_ON
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef SYNTHESIS
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef ASSERT_OFF_RESET_IS_X
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b0 : nvdla_core_rstn)
`else
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b1 : nvdla_core_rstn)
`endif // ASSERT_OFF_RESET_IS_X
`endif // SYNTHESIS
`endif // FV_ASSERT_ON
`ifndef SYNTHESIS
// VCS coverage off
nv_assert_no_x #(0,1,0,"No X's allowed on control signals") zzz_assert_no_x_1x (nvdla_core_clk, `ASSERT_RESET, 1'd1, (^(dp2reg_done))); // spyglass disable W504 SelfDeterminedExpr-ML
// VCS coverage on
`endif
`undef ASSERT_RESET
`endif // ASSERT_ON
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass enable_block NoWidthInBasedNum-ML
// spyglass enable_block STARC-2.10.3.2a
// spyglass enable_block STARC05-2.1.3.1
// spyglass enable_block STARC-2.1.4.6
// spyglass enable_block W116
// spyglass enable_block W154
// spyglass enable_block W239
// spyglass enable_block W362
// spyglass enable_block WRN_58
// spyglass enable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
////////////////////////////////////////////////////////////////////////
// //
// GENERATE TWO STATUS FIELDS IN GENERAL SINGLE REGISTER GROUP //
// //
////////////////////////////////////////////////////////////////////////
always @(
reg2dp_d0_op_en
or dp2reg_consumer
) begin
dp2reg_status_0 = (reg2dp_d0_op_en == 1'h0 ) ? 2'h0 :
(dp2reg_consumer == 1'h1 ) ? 2'h2 :
2'h1 ;
end
always @(
reg2dp_d1_op_en
or dp2reg_consumer
) begin
dp2reg_status_1 = (reg2dp_d1_op_en == 1'h0 ) ? 2'h0 :
(dp2reg_consumer == 1'h0 ) ? 2'h2 :
2'h1 ;
end
////////////////////////////////////////////////////////////////////////
// //
// GENERATE OP_EN LOGIC //
// //
////////////////////////////////////////////////////////////////////////
always @(
reg2dp_d0_op_en
or reg2dp_d0_op_en_trigger
or reg_wr_data
or dp2reg_done
or dp2reg_consumer
) begin
reg2dp_d0_op_en_w = (~reg2dp_d0_op_en & reg2dp_d0_op_en_trigger) ? reg_wr_data[0 ] :
(dp2reg_done && dp2reg_consumer == 1'h0 ) ? 1'b0 :
reg2dp_d0_op_en;
end
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
reg2dp_d0_op_en <= 1'b0;
end else begin
reg2dp_d0_op_en <= reg2dp_d0_op_en_w;
end
end
always @(
reg2dp_d1_op_en
or reg2dp_d1_op_en_trigger
or reg_wr_data
or dp2reg_done
or dp2reg_consumer
) begin
reg2dp_d1_op_en_w = (~reg2dp_d1_op_en & reg2dp_d1_op_en_trigger) ? reg_wr_data[0 ] :
(dp2reg_done && dp2reg_consumer == 1'h1 ) ? 1'b0 :
reg2dp_d1_op_en;
end
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
reg2dp_d1_op_en <= 1'b0;
end else begin
reg2dp_d1_op_en <= reg2dp_d1_op_en_w;
end
end
always @(
dp2reg_consumer
or reg2dp_d1_op_en
or reg2dp_d0_op_en
) begin
reg2dp_op_en_ori = dp2reg_consumer ? reg2dp_d1_op_en : reg2dp_d0_op_en;
end
assign reg2dp_op_en_reg_w = dp2reg_done ? 3'b0 :
{reg2dp_op_en_reg[1:0], reg2dp_op_en_ori};
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
reg2dp_op_en_reg <= {3{1'b0}};
end else begin
reg2dp_op_en_reg <= reg2dp_op_en_reg_w;
end
end
assign reg2dp_op_en = reg2dp_op_en_reg[3-1];
assign slcg_op_en_d0 = {3{reg2dp_op_en_ori}};
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
slcg_op_en_d1 <= {3{1'b0}};
end else begin
slcg_op_en_d1 <= slcg_op_en_d0;
end
end
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
slcg_op_en_d2 <= {3{1'b0}};
end else begin
slcg_op_en_d2 <= slcg_op_en_d1;
end
end
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
slcg_op_en_d3 <= {3{1'b0}};
end else begin
slcg_op_en_d3 <= slcg_op_en_d2;
end
end
assign slcg_op_en = slcg_op_en_d3;
////////////////////////////////////////////////////////////////////////
// //
// GENERATE ACCESS LOGIC TO EACH REGISTER GROUP //
// //
////////////////////////////////////////////////////////////////////////
//EACH subunit has 4KB address space
assign select_s = (reg_offset[11:0] < (32'hd008 & 32'hfff)) ? 1'b1: 1'b0;
assign select_d0 = (reg_offset[11:0] >= (32'hd008 & 32'hfff)) & (reg2dp_producer == 1'h0 );
assign select_d1 = (reg_offset[11:0] >= (32'hd008 & 32'hfff)) & (reg2dp_producer == 1'h1 );
assign s_reg_wr_en = reg_wr_en & select_s;
assign d0_reg_wr_en = reg_wr_en & select_d0 & ~reg2dp_d0_op_en;
assign d1_reg_wr_en = reg_wr_en & select_d1 & ~reg2dp_d1_op_en;
assign s_reg_offset = reg_offset;
assign d0_reg_offset = reg_offset;
assign d1_reg_offset = reg_offset;
assign s_reg_wr_data = reg_wr_data;
assign d0_reg_wr_data = reg_wr_data;
assign d1_reg_wr_data = reg_wr_data;
assign reg_rd_data = ({32{select_s}} & s_reg_rd_data) |
({32{select_d0}} & d0_reg_rd_data) |
({32{select_d1}} & d1_reg_rd_data);
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass disable_block NoWidthInBasedNum-ML
// spyglass disable_block STARC-2.10.3.2a
// spyglass disable_block STARC05-2.1.3.1
// spyglass disable_block STARC-2.1.4.6
// spyglass disable_block W116
// spyglass disable_block W154
// spyglass disable_block W239
// spyglass disable_block W362
// spyglass disable_block WRN_58
// spyglass disable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
`ifdef ASSERT_ON
`ifdef FV_ASSERT_ON
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef SYNTHESIS
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef ASSERT_OFF_RESET_IS_X
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b0 : nvdla_core_rstn)
`else
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b1 : nvdla_core_rstn)
`endif // ASSERT_OFF_RESET_IS_X
`endif // SYNTHESIS
`endif // FV_ASSERT_ON
`ifndef SYNTHESIS
// VCS coverage off
nv_assert_never #(0,0,"Error! Write group 0 registers when OP_EN is set!") zzz_assert_never_2x (nvdla_core_clk, `ASSERT_RESET, (reg_wr_en & select_d0 & reg2dp_d0_op_en)); // spyglass disable W504 SelfDeterminedExpr-ML
// VCS coverage on
`endif
`undef ASSERT_RESET
`endif // ASSERT_ON
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass enable_block NoWidthInBasedNum-ML
// spyglass enable_block STARC-2.10.3.2a
// spyglass enable_block STARC05-2.1.3.1
// spyglass enable_block STARC-2.1.4.6
// spyglass enable_block W116
// spyglass enable_block W154
// spyglass enable_block W239
// spyglass enable_block W362
// spyglass enable_block WRN_58
// spyglass enable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass disable_block NoWidthInBasedNum-ML
// spyglass disable_block STARC-2.10.3.2a
// spyglass disable_block STARC05-2.1.3.1
// spyglass disable_block STARC-2.1.4.6
// spyglass disable_block W116
// spyglass disable_block W154
// spyglass disable_block W239
// spyglass disable_block W362
// spyglass disable_block WRN_58
// spyglass disable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
`ifdef ASSERT_ON
`ifdef FV_ASSERT_ON
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef SYNTHESIS
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef ASSERT_OFF_RESET_IS_X
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b0 : nvdla_core_rstn)
`else
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b1 : nvdla_core_rstn)
`endif // ASSERT_OFF_RESET_IS_X
`endif // SYNTHESIS
`endif // FV_ASSERT_ON
`ifndef SYNTHESIS
// VCS coverage off
nv_assert_never #(0,0,"Error! Write group 1 registers when OP_EN is set!") zzz_assert_never_3x (nvdla_core_clk, `ASSERT_RESET, (reg_wr_en & select_d1 & reg2dp_d1_op_en)); // spyglass disable W504 SelfDeterminedExpr-ML
// VCS coverage on
`endif
`undef ASSERT_RESET
`endif // ASSERT_ON
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass enable_block NoWidthInBasedNum-ML
// spyglass enable_block STARC-2.10.3.2a
// spyglass enable_block STARC05-2.1.3.1
// spyglass enable_block STARC-2.1.4.6
// spyglass enable_block W116
// spyglass enable_block W154
// spyglass enable_block W239
// spyglass enable_block W362
// spyglass enable_block WRN_58
// spyglass enable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
////////////////////////////////////////////////////////////////////////
// //
// GENERATE CSB TO REGISTER CONNECTION LOGIC //
// //
////////////////////////////////////////////////////////////////////////
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
req_pvld <= 1'b0;
end else begin
req_pvld <= csb2pdp_req_pvld;
end
end
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
req_pd <= {63{1'b0}};
end else begin
if ((csb2pdp_req_pvld) == 1'b1) begin
req_pd <= csb2pdp_req_pd;
// VCS coverage off
end else if ((csb2pdp_req_pvld) == 1'b0) begin
end else begin
req_pd <= 'bx; // spyglass disable STARC-2.10.1.6 W443 NoWidthInBasedNum-ML -- (Constant containing x or z used, Based number `bx contains an X, Width specification missing for based number)
// VCS coverage on
end
end
end
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass disable_block NoWidthInBasedNum-ML
// spyglass disable_block STARC-2.10.3.2a
// spyglass disable_block STARC05-2.1.3.1
// spyglass disable_block STARC-2.1.4.6
// spyglass disable_block W116
// spyglass disable_block W154
// spyglass disable_block W239
// spyglass disable_block W362
// spyglass disable_block WRN_58
// spyglass disable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
`ifdef ASSERT_ON
`ifdef FV_ASSERT_ON
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef SYNTHESIS
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef ASSERT_OFF_RESET_IS_X
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b0 : nvdla_core_rstn)
`else
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b1 : nvdla_core_rstn)
`endif // ASSERT_OFF_RESET_IS_X
`endif // SYNTHESIS
`endif // FV_ASSERT_ON
`ifndef SYNTHESIS
// VCS coverage off
nv_assert_no_x #(0,1,0,"No X's allowed on control signals") zzz_assert_no_x_4x (nvdla_core_clk, `ASSERT_RESET, 1'd1, (^(csb2pdp_req_pvld))); // spyglass disable W504 SelfDeterminedExpr-ML
// VCS coverage on
`endif
`undef ASSERT_RESET
`endif // ASSERT_ON
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass enable_block NoWidthInBasedNum-ML
// spyglass enable_block STARC-2.10.3.2a
// spyglass enable_block STARC05-2.1.3.1
// spyglass enable_block STARC-2.1.4.6
// spyglass enable_block W116
// spyglass enable_block W154
// spyglass enable_block W239
// spyglass enable_block W362
// spyglass enable_block WRN_58
// spyglass enable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
// PKT_UNPACK_WIRE( csb2xx_16m_be_lvl , req_ , req_pd )
assign req_addr[21:0] = req_pd[21:0];
assign req_wdat[31:0] = req_pd[53:22];
assign req_write = req_pd[54];
assign req_nposted = req_pd[55];
assign req_srcpriv = req_pd[56];
assign req_wrbe[3:0] = req_pd[60:57];
assign req_level[1:0] = req_pd[62:61];
assign csb2pdp_req_prdy = 1'b1;
//Address in CSB master is word aligned while address in regfile is byte aligned.
assign reg_offset = {req_addr, 2'b0};
assign reg_wr_data = req_wdat;
assign reg_wr_en = req_pvld & req_write;
assign reg_rd_en = req_pvld & ~req_write;
// PKT_PACK_WIRE_ID( nvdla_xx2csb_resp , dla_xx2csb_rd_erpt , csb_rresp_ , csb_rresp_pd_w )
assign csb_rresp_pd_w[31:0] = csb_rresp_rdat[31:0];
assign csb_rresp_pd_w[32] = csb_rresp_error ;
assign csb_rresp_pd_w[33:33] = 1'd0 /* PKT_nvdla_xx2csb_resp_dla_xx2csb_rd_erpt_ID */ ;
// PKT_PACK_WIRE_ID( nvdla_xx2csb_resp , dla_xx2csb_wr_erpt , csb_wresp_ , csb_wresp_pd_w )
assign csb_wresp_pd_w[31:0] = csb_wresp_rdat[31:0];
assign csb_wresp_pd_w[32] = csb_wresp_error ;
assign csb_wresp_pd_w[33:33] = 1'd1 /* PKT_nvdla_xx2csb_resp_dla_xx2csb_wr_erpt_ID */ ;
assign csb_rresp_rdat = reg_rd_data;
assign csb_rresp_error = 1'b0;
assign csb_wresp_rdat = {32{1'b0}};
assign csb_wresp_error = 1'b0;
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
pdp2csb_resp_pd <= {34{1'b0}};
end else begin
if(reg_rd_en)
begin
pdp2csb_resp_pd <= csb_rresp_pd_w;
end
else if(reg_wr_en & req_nposted)
begin
pdp2csb_resp_pd <= csb_wresp_pd_w;
end
end
end
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
pdp2csb_resp_valid <= 1'b0;
end else begin
pdp2csb_resp_valid <= (reg_wr_en & req_nposted) | reg_rd_en;
end
end
////////////////////////////////////////////////////////////////////////
// //
// GENERATE OUTPUT REGISTER FILED FROM DUPLICATED REGISTER GROUPS //
// //
////////////////////////////////////////////////////////////////////////
always @(
dp2reg_consumer
or reg2dp_d1_cya
or reg2dp_d0_cya
) begin
reg2dp_cya = dp2reg_consumer ? reg2dp_d1_cya : reg2dp_d0_cya;
end
always @(
dp2reg_consumer
or reg2dp_d1_cube_in_channel
or reg2dp_d0_cube_in_channel
) begin
reg2dp_cube_in_channel = dp2reg_consumer ? reg2dp_d1_cube_in_channel : reg2dp_d0_cube_in_channel;
end
always @(
dp2reg_consumer
or reg2dp_d1_cube_in_height
or reg2dp_d0_cube_in_height
) begin
reg2dp_cube_in_height = dp2reg_consumer ? reg2dp_d1_cube_in_height : reg2dp_d0_cube_in_height;
end
always @(
dp2reg_consumer
or reg2dp_d1_cube_in_width
or reg2dp_d0_cube_in_width
) begin
reg2dp_cube_in_width = dp2reg_consumer ? reg2dp_d1_cube_in_width : reg2dp_d0_cube_in_width;
end
always @(
dp2reg_consumer
or reg2dp_d1_cube_out_channel
or reg2dp_d0_cube_out_channel
) begin
reg2dp_cube_out_channel = dp2reg_consumer ? reg2dp_d1_cube_out_channel : reg2dp_d0_cube_out_channel;
end
always @(
dp2reg_consumer
or reg2dp_d1_cube_out_height
or reg2dp_d0_cube_out_height
) begin
reg2dp_cube_out_height = dp2reg_consumer ? reg2dp_d1_cube_out_height : reg2dp_d0_cube_out_height;
end
always @(
dp2reg_consumer
or reg2dp_d1_cube_out_width
or reg2dp_d0_cube_out_width
) begin
reg2dp_cube_out_width = dp2reg_consumer ? reg2dp_d1_cube_out_width : reg2dp_d0_cube_out_width;
end
always @(
dp2reg_consumer
or reg2dp_d1_input_data
or reg2dp_d0_input_data
) begin
reg2dp_input_data = dp2reg_consumer ? reg2dp_d1_input_data : reg2dp_d0_input_data;
end
always @(
dp2reg_consumer
or reg2dp_d1_dst_base_addr_high
or reg2dp_d0_dst_base_addr_high
) begin
reg2dp_dst_base_addr_high = dp2reg_consumer ? reg2dp_d1_dst_base_addr_high : reg2dp_d0_dst_base_addr_high;
end
always @(
dp2reg_consumer
or reg2dp_d1_dst_base_addr_low
or reg2dp_d0_dst_base_addr_low
) begin
reg2dp_dst_base_addr_low = dp2reg_consumer ? reg2dp_d1_dst_base_addr_low : reg2dp_d0_dst_base_addr_low;
end
always @(
dp2reg_consumer
or reg2dp_d1_dst_line_stride
or reg2dp_d0_dst_line_stride
) begin
reg2dp_dst_line_stride = dp2reg_consumer ? reg2dp_d1_dst_line_stride : reg2dp_d0_dst_line_stride;
end
always @(
dp2reg_consumer
or reg2dp_d1_dst_ram_type
or reg2dp_d0_dst_ram_type
) begin
reg2dp_dst_ram_type = dp2reg_consumer ? reg2dp_d1_dst_ram_type : reg2dp_d0_dst_ram_type;
end
always @(
dp2reg_consumer
or reg2dp_d1_dst_surface_stride
or reg2dp_d0_dst_surface_stride
) begin
reg2dp_dst_surface_stride = dp2reg_consumer ? reg2dp_d1_dst_surface_stride : reg2dp_d0_dst_surface_stride;
end
always @(
dp2reg_consumer
or reg2dp_d1_nan_to_zero
or reg2dp_d0_nan_to_zero
) begin
reg2dp_nan_to_zero = dp2reg_consumer ? reg2dp_d1_nan_to_zero : reg2dp_d0_nan_to_zero;
end
always @(
dp2reg_consumer
or reg2dp_d1_flying_mode
or reg2dp_d0_flying_mode
) begin
reg2dp_flying_mode = dp2reg_consumer ? reg2dp_d1_flying_mode : reg2dp_d0_flying_mode;
end
always @(
dp2reg_consumer
or reg2dp_d1_pooling_method
or reg2dp_d0_pooling_method
) begin
reg2dp_pooling_method = dp2reg_consumer ? reg2dp_d1_pooling_method : reg2dp_d0_pooling_method;
end
always @(
dp2reg_consumer
or reg2dp_d1_split_num
or reg2dp_d0_split_num
) begin
reg2dp_split_num = dp2reg_consumer ? reg2dp_d1_split_num : reg2dp_d0_split_num;
end
always @(
dp2reg_consumer
or reg2dp_d1_partial_width_in_first
or reg2dp_d0_partial_width_in_first
) begin
reg2dp_partial_width_in_first = dp2reg_consumer ? reg2dp_d1_partial_width_in_first : reg2dp_d0_partial_width_in_first;
end
always @(
dp2reg_consumer
or reg2dp_d1_partial_width_in_last
or reg2dp_d0_partial_width_in_last
) begin
reg2dp_partial_width_in_last = dp2reg_consumer ? reg2dp_d1_partial_width_in_last : reg2dp_d0_partial_width_in_last;
end
always @(
dp2reg_consumer
or reg2dp_d1_partial_width_in_mid
or reg2dp_d0_partial_width_in_mid
) begin
reg2dp_partial_width_in_mid = dp2reg_consumer ? reg2dp_d1_partial_width_in_mid : reg2dp_d0_partial_width_in_mid;
end
always @(
dp2reg_consumer
or reg2dp_d1_partial_width_out_first
or reg2dp_d0_partial_width_out_first
) begin
reg2dp_partial_width_out_first = dp2reg_consumer ? reg2dp_d1_partial_width_out_first : reg2dp_d0_partial_width_out_first;
end
always @(
dp2reg_consumer
or reg2dp_d1_partial_width_out_last
or reg2dp_d0_partial_width_out_last
) begin
reg2dp_partial_width_out_last = dp2reg_consumer ? reg2dp_d1_partial_width_out_last : reg2dp_d0_partial_width_out_last;
end
always @(
dp2reg_consumer
or reg2dp_d1_partial_width_out_mid
or reg2dp_d0_partial_width_out_mid
) begin
reg2dp_partial_width_out_mid = dp2reg_consumer ? reg2dp_d1_partial_width_out_mid : reg2dp_d0_partial_width_out_mid;
end
always @(
dp2reg_consumer
or reg2dp_d1_dma_en
or reg2dp_d0_dma_en
) begin
reg2dp_dma_en = dp2reg_consumer ? reg2dp_d1_dma_en : reg2dp_d0_dma_en;
end
always @(
dp2reg_consumer
or reg2dp_d1_kernel_height
or reg2dp_d0_kernel_height
) begin
reg2dp_kernel_height = dp2reg_consumer ? reg2dp_d1_kernel_height : reg2dp_d0_kernel_height;
end
always @(
dp2reg_consumer
or reg2dp_d1_kernel_stride_height
or reg2dp_d0_kernel_stride_height
) begin
reg2dp_kernel_stride_height = dp2reg_consumer ? reg2dp_d1_kernel_stride_height : reg2dp_d0_kernel_stride_height;
end
always @(
dp2reg_consumer
or reg2dp_d1_kernel_stride_width
or reg2dp_d0_kernel_stride_width
) begin
reg2dp_kernel_stride_width = dp2reg_consumer ? reg2dp_d1_kernel_stride_width : reg2dp_d0_kernel_stride_width;
end
always @(
dp2reg_consumer
or reg2dp_d1_kernel_width
or reg2dp_d0_kernel_width
) begin
reg2dp_kernel_width = dp2reg_consumer ? reg2dp_d1_kernel_width : reg2dp_d0_kernel_width;
end
always @(
dp2reg_consumer
or reg2dp_d1_pad_bottom
or reg2dp_d0_pad_bottom
) begin
reg2dp_pad_bottom = dp2reg_consumer ? reg2dp_d1_pad_bottom : reg2dp_d0_pad_bottom;
end
always @(
dp2reg_consumer
or reg2dp_d1_pad_left
or reg2dp_d0_pad_left
) begin
reg2dp_pad_left = dp2reg_consumer ? reg2dp_d1_pad_left : reg2dp_d0_pad_left;
end
always @(
dp2reg_consumer
or reg2dp_d1_pad_right
or reg2dp_d0_pad_right
) begin
reg2dp_pad_right = dp2reg_consumer ? reg2dp_d1_pad_right : reg2dp_d0_pad_right;
end
always @(
dp2reg_consumer
or reg2dp_d1_pad_top
or reg2dp_d0_pad_top
) begin
reg2dp_pad_top = dp2reg_consumer ? reg2dp_d1_pad_top : reg2dp_d0_pad_top;
end
always @(
dp2reg_consumer
or reg2dp_d1_pad_value_1x
or reg2dp_d0_pad_value_1x
) begin
reg2dp_pad_value_1x = dp2reg_consumer ? reg2dp_d1_pad_value_1x : reg2dp_d0_pad_value_1x;
end
always @(
dp2reg_consumer
or reg2dp_d1_pad_value_2x
or reg2dp_d0_pad_value_2x
) begin
reg2dp_pad_value_2x = dp2reg_consumer ? reg2dp_d1_pad_value_2x : reg2dp_d0_pad_value_2x;
end
always @(
dp2reg_consumer
or reg2dp_d1_pad_value_3x
or reg2dp_d0_pad_value_3x
) begin
reg2dp_pad_value_3x = dp2reg_consumer ? reg2dp_d1_pad_value_3x : reg2dp_d0_pad_value_3x;
end
always @(
dp2reg_consumer
or reg2dp_d1_pad_value_4x
or reg2dp_d0_pad_value_4x
) begin
reg2dp_pad_value_4x = dp2reg_consumer ? reg2dp_d1_pad_value_4x : reg2dp_d0_pad_value_4x;
end
always @(
dp2reg_consumer
or reg2dp_d1_pad_value_5x
or reg2dp_d0_pad_value_5x
) begin
reg2dp_pad_value_5x = dp2reg_consumer ? reg2dp_d1_pad_value_5x : reg2dp_d0_pad_value_5x;
end
always @(
dp2reg_consumer
or reg2dp_d1_pad_value_6x
or reg2dp_d0_pad_value_6x
) begin
reg2dp_pad_value_6x = dp2reg_consumer ? reg2dp_d1_pad_value_6x : reg2dp_d0_pad_value_6x;
end
always @(
dp2reg_consumer
or reg2dp_d1_pad_value_7x
or reg2dp_d0_pad_value_7x
) begin
reg2dp_pad_value_7x = dp2reg_consumer ? reg2dp_d1_pad_value_7x : reg2dp_d0_pad_value_7x;
end
always @(
dp2reg_consumer
or reg2dp_d1_recip_kernel_height
or reg2dp_d0_recip_kernel_height
) begin
reg2dp_recip_kernel_height = dp2reg_consumer ? reg2dp_d1_recip_kernel_height : reg2dp_d0_recip_kernel_height;
end
always @(
dp2reg_consumer
or reg2dp_d1_recip_kernel_width
or reg2dp_d0_recip_kernel_width
) begin
reg2dp_recip_kernel_width = dp2reg_consumer ? reg2dp_d1_recip_kernel_width : reg2dp_d0_recip_kernel_width;
end
always @(
dp2reg_consumer
or reg2dp_d1_src_base_addr_high
or reg2dp_d0_src_base_addr_high
) begin
reg2dp_src_base_addr_high = dp2reg_consumer ? reg2dp_d1_src_base_addr_high : reg2dp_d0_src_base_addr_high;
end
always @(
dp2reg_consumer
or reg2dp_d1_src_base_addr_low
or reg2dp_d0_src_base_addr_low
) begin
reg2dp_src_base_addr_low = dp2reg_consumer ? reg2dp_d1_src_base_addr_low : reg2dp_d0_src_base_addr_low;
end
always @(
dp2reg_consumer
or reg2dp_d1_src_line_stride
or reg2dp_d0_src_line_stride
) begin
reg2dp_src_line_stride = dp2reg_consumer ? reg2dp_d1_src_line_stride : reg2dp_d0_src_line_stride;
end
always @(
dp2reg_consumer
or reg2dp_d1_src_surface_stride
or reg2dp_d0_src_surface_stride
) begin
reg2dp_src_surface_stride = dp2reg_consumer ? reg2dp_d1_src_surface_stride : reg2dp_d0_src_surface_stride;
end
////////////////////////////////////////////////////////////////////////
// //
// PASTE ADDIFITON LOGIC HERE FROM EXTRA FILE //
// //
////////////////////////////////////////////////////////////////////////
//assign reg2dp_lut_data = reg_wr_data[::range(15)];
assign reg2dp_interrupt_ptr = dp2reg_consumer;
//////// for general counting register ////////
always @(
reg2dp_d0_op_en
or reg2dp_d0_op_en_w
) begin
dp2reg_d0_set = reg2dp_d0_op_en & ~reg2dp_d0_op_en_w;
dp2reg_d0_clr = ~reg2dp_d0_op_en & reg2dp_d0_op_en_w;
dp2reg_d0_reg = reg2dp_d0_op_en ^ reg2dp_d0_op_en_w;
end
always @(
reg2dp_d1_op_en
or reg2dp_d1_op_en_w
) begin
dp2reg_d1_set = reg2dp_d1_op_en & ~reg2dp_d1_op_en_w;
dp2reg_d1_clr = ~reg2dp_d1_op_en & reg2dp_d1_op_en_w;
dp2reg_d1_reg = reg2dp_d1_op_en ^ reg2dp_d1_op_en_w;
end
//////// for NaN and infinity counting registers ////////
//////// group 0 ////////
always @(
dp2reg_d0_set
or dp2reg_nan_input_num
or dp2reg_d0_clr
or dp2reg_d0_nan_input_num
) begin
dp2reg_d0_nan_input_num_w = (dp2reg_d0_set) ? dp2reg_nan_input_num :
(dp2reg_d0_clr) ? 32'b0 :
dp2reg_d0_nan_input_num;
end
always @(
dp2reg_d0_set
or dp2reg_inf_input_num
or dp2reg_d0_clr
or dp2reg_d0_inf_input_num
) begin
dp2reg_d0_inf_input_num_w = (dp2reg_d0_set) ? dp2reg_inf_input_num :
(dp2reg_d0_clr) ? 32'b0 :
dp2reg_d0_inf_input_num;
end
always @(
dp2reg_d0_set
or dp2reg_nan_output_num
or dp2reg_d0_clr
or dp2reg_d0_nan_output_num
) begin
dp2reg_d0_nan_output_num_w = (dp2reg_d0_set) ? dp2reg_nan_output_num :
(dp2reg_d0_clr) ? 32'b0 :
dp2reg_d0_nan_output_num;
end
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
dp2reg_d0_nan_input_num <= {32{1'b0}};
end else begin
if ((dp2reg_d0_reg) == 1'b1) begin
dp2reg_d0_nan_input_num <= dp2reg_d0_nan_input_num_w;
// VCS coverage off
end else if ((dp2reg_d0_reg) == 1'b0) begin
end else begin
dp2reg_d0_nan_input_num <= 'bx; // spyglass disable STARC-2.10.1.6 W443 NoWidthInBasedNum-ML -- (Constant containing x or z used, Based number `bx contains an X, Width specification missing for based number)
// VCS coverage on
end
end
end
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass disable_block NoWidthInBasedNum-ML
// spyglass disable_block STARC-2.10.3.2a
// spyglass disable_block STARC05-2.1.3.1
// spyglass disable_block STARC-2.1.4.6
// spyglass disable_block W116
// spyglass disable_block W154
// spyglass disable_block W239
// spyglass disable_block W362
// spyglass disable_block WRN_58
// spyglass disable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
`ifdef ASSERT_ON
`ifdef FV_ASSERT_ON
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef SYNTHESIS
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef ASSERT_OFF_RESET_IS_X
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b0 : nvdla_core_rstn)
`else
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b1 : nvdla_core_rstn)
`endif // ASSERT_OFF_RESET_IS_X
`endif // SYNTHESIS
`endif // FV_ASSERT_ON
`ifndef SYNTHESIS
// VCS coverage off
nv_assert_no_x #(0,1,0,"No X's allowed on control signals") zzz_assert_no_x_5x (nvdla_core_clk, `ASSERT_RESET, 1'd1, (^(dp2reg_d0_reg))); // spyglass disable W504 SelfDeterminedExpr-ML
// VCS coverage on
`endif
`undef ASSERT_RESET
`endif // ASSERT_ON
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass enable_block NoWidthInBasedNum-ML
// spyglass enable_block STARC-2.10.3.2a
// spyglass enable_block STARC05-2.1.3.1
// spyglass enable_block STARC-2.1.4.6
// spyglass enable_block W116
// spyglass enable_block W154
// spyglass enable_block W239
// spyglass enable_block W362
// spyglass enable_block WRN_58
// spyglass enable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
dp2reg_d0_inf_input_num <= {32{1'b0}};
end else begin
if ((dp2reg_d0_reg) == 1'b1) begin
dp2reg_d0_inf_input_num <= dp2reg_d0_inf_input_num_w;
// VCS coverage off
end else if ((dp2reg_d0_reg) == 1'b0) begin
end else begin
dp2reg_d0_inf_input_num <= 'bx; // spyglass disable STARC-2.10.1.6 W443 NoWidthInBasedNum-ML -- (Constant containing x or z used, Based number `bx contains an X, Width specification missing for based number)
// VCS coverage on
end
end
end
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass disable_block NoWidthInBasedNum-ML
// spyglass disable_block STARC-2.10.3.2a
// spyglass disable_block STARC05-2.1.3.1
// spyglass disable_block STARC-2.1.4.6
// spyglass disable_block W116
// spyglass disable_block W154
// spyglass disable_block W239
// spyglass disable_block W362
// spyglass disable_block WRN_58
// spyglass disable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
`ifdef ASSERT_ON
`ifdef FV_ASSERT_ON
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef SYNTHESIS
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef ASSERT_OFF_RESET_IS_X
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b0 : nvdla_core_rstn)
`else
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b1 : nvdla_core_rstn)
`endif // ASSERT_OFF_RESET_IS_X
`endif // SYNTHESIS
`endif // FV_ASSERT_ON
`ifndef SYNTHESIS
// VCS coverage off
nv_assert_no_x #(0,1,0,"No X's allowed on control signals") zzz_assert_no_x_6x (nvdla_core_clk, `ASSERT_RESET, 1'd1, (^(dp2reg_d0_reg))); // spyglass disable W504 SelfDeterminedExpr-ML
// VCS coverage on
`endif
`undef ASSERT_RESET
`endif // ASSERT_ON
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass enable_block NoWidthInBasedNum-ML
// spyglass enable_block STARC-2.10.3.2a
// spyglass enable_block STARC05-2.1.3.1
// spyglass enable_block STARC-2.1.4.6
// spyglass enable_block W116
// spyglass enable_block W154
// spyglass enable_block W239
// spyglass enable_block W362
// spyglass enable_block WRN_58
// spyglass enable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
dp2reg_d0_nan_output_num <= {32{1'b0}};
end else begin
if ((dp2reg_d0_reg) == 1'b1) begin
dp2reg_d0_nan_output_num <= dp2reg_d0_nan_output_num_w;
// VCS coverage off
end else if ((dp2reg_d0_reg) == 1'b0) begin
end else begin
dp2reg_d0_nan_output_num <= 'bx; // spyglass disable STARC-2.10.1.6 W443 NoWidthInBasedNum-ML -- (Constant containing x or z used, Based number `bx contains an X, Width specification missing for based number)
// VCS coverage on
end
end
end
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass disable_block NoWidthInBasedNum-ML
// spyglass disable_block STARC-2.10.3.2a
// spyglass disable_block STARC05-2.1.3.1
// spyglass disable_block STARC-2.1.4.6
// spyglass disable_block W116
// spyglass disable_block W154
// spyglass disable_block W239
// spyglass disable_block W362
// spyglass disable_block WRN_58
// spyglass disable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
`ifdef ASSERT_ON
`ifdef FV_ASSERT_ON
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef SYNTHESIS
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef ASSERT_OFF_RESET_IS_X
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b0 : nvdla_core_rstn)
`else
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b1 : nvdla_core_rstn)
`endif // ASSERT_OFF_RESET_IS_X
`endif // SYNTHESIS
`endif // FV_ASSERT_ON
`ifndef SYNTHESIS
// VCS coverage off
nv_assert_no_x #(0,1,0,"No X's allowed on control signals") zzz_assert_no_x_7x (nvdla_core_clk, `ASSERT_RESET, 1'd1, (^(dp2reg_d0_reg))); // spyglass disable W504 SelfDeterminedExpr-ML
// VCS coverage on
`endif
`undef ASSERT_RESET
`endif // ASSERT_ON
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass enable_block NoWidthInBasedNum-ML
// spyglass enable_block STARC-2.10.3.2a
// spyglass enable_block STARC05-2.1.3.1
// spyglass enable_block STARC-2.1.4.6
// spyglass enable_block W116
// spyglass enable_block W154
// spyglass enable_block W239
// spyglass enable_block W362
// spyglass enable_block WRN_58
// spyglass enable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
//////// group 1 ////////
always @(
dp2reg_d1_set
or dp2reg_nan_input_num
or dp2reg_d1_clr
or dp2reg_d1_nan_input_num
) begin
dp2reg_d1_nan_input_num_w = (dp2reg_d1_set) ? dp2reg_nan_input_num :
(dp2reg_d1_clr) ? 32'b0 :
dp2reg_d1_nan_input_num;
end
always @(
dp2reg_d1_set
or dp2reg_inf_input_num
or dp2reg_d1_clr
or dp2reg_d1_inf_input_num
) begin
dp2reg_d1_inf_input_num_w = (dp2reg_d1_set) ? dp2reg_inf_input_num :
(dp2reg_d1_clr) ? 32'b0 :
dp2reg_d1_inf_input_num;
end
always @(
dp2reg_d1_set
or dp2reg_nan_output_num
or dp2reg_d1_clr
or dp2reg_d1_nan_output_num
) begin
dp2reg_d1_nan_output_num_w = (dp2reg_d1_set) ? dp2reg_nan_output_num :
(dp2reg_d1_clr) ? 32'b0 :
dp2reg_d1_nan_output_num;
end
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
dp2reg_d1_nan_input_num <= {32{1'b0}};
end else begin
if ((dp2reg_d1_reg) == 1'b1) begin
dp2reg_d1_nan_input_num <= dp2reg_d1_nan_input_num_w;
// VCS coverage off
end else if ((dp2reg_d1_reg) == 1'b0) begin
end else begin
dp2reg_d1_nan_input_num <= 'bx; // spyglass disable STARC-2.10.1.6 W443 NoWidthInBasedNum-ML -- (Constant containing x or z used, Based number `bx contains an X, Width specification missing for based number)
// VCS coverage on
end
end
end
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass disable_block NoWidthInBasedNum-ML
// spyglass disable_block STARC-2.10.3.2a
// spyglass disable_block STARC05-2.1.3.1
// spyglass disable_block STARC-2.1.4.6
// spyglass disable_block W116
// spyglass disable_block W154
// spyglass disable_block W239
// spyglass disable_block W362
// spyglass disable_block WRN_58
// spyglass disable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
`ifdef ASSERT_ON
`ifdef FV_ASSERT_ON
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef SYNTHESIS
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef ASSERT_OFF_RESET_IS_X
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b0 : nvdla_core_rstn)
`else
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b1 : nvdla_core_rstn)
`endif // ASSERT_OFF_RESET_IS_X
`endif // SYNTHESIS
`endif // FV_ASSERT_ON
`ifndef SYNTHESIS
// VCS coverage off
nv_assert_no_x #(0,1,0,"No X's allowed on control signals") zzz_assert_no_x_8x (nvdla_core_clk, `ASSERT_RESET, 1'd1, (^(dp2reg_d1_reg))); // spyglass disable W504 SelfDeterminedExpr-ML
// VCS coverage on
`endif
`undef ASSERT_RESET
`endif // ASSERT_ON
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass enable_block NoWidthInBasedNum-ML
// spyglass enable_block STARC-2.10.3.2a
// spyglass enable_block STARC05-2.1.3.1
// spyglass enable_block STARC-2.1.4.6
// spyglass enable_block W116
// spyglass enable_block W154
// spyglass enable_block W239
// spyglass enable_block W362
// spyglass enable_block WRN_58
// spyglass enable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
dp2reg_d1_inf_input_num <= {32{1'b0}};
end else begin
if ((dp2reg_d1_reg) == 1'b1) begin
dp2reg_d1_inf_input_num <= dp2reg_d1_inf_input_num_w;
// VCS coverage off
end else if ((dp2reg_d1_reg) == 1'b0) begin
end else begin
dp2reg_d1_inf_input_num <= 'bx; // spyglass disable STARC-2.10.1.6 W443 NoWidthInBasedNum-ML -- (Constant containing x or z used, Based number `bx contains an X, Width specification missing for based number)
// VCS coverage on
end
end
end
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass disable_block NoWidthInBasedNum-ML
// spyglass disable_block STARC-2.10.3.2a
// spyglass disable_block STARC05-2.1.3.1
// spyglass disable_block STARC-2.1.4.6
// spyglass disable_block W116
// spyglass disable_block W154
// spyglass disable_block W239
// spyglass disable_block W362
// spyglass disable_block WRN_58
// spyglass disable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
`ifdef ASSERT_ON
`ifdef FV_ASSERT_ON
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef SYNTHESIS
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef ASSERT_OFF_RESET_IS_X
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b0 : nvdla_core_rstn)
`else
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b1 : nvdla_core_rstn)
`endif // ASSERT_OFF_RESET_IS_X
`endif // SYNTHESIS
`endif // FV_ASSERT_ON
`ifndef SYNTHESIS
// VCS coverage off
nv_assert_no_x #(0,1,0,"No X's allowed on control signals") zzz_assert_no_x_9x (nvdla_core_clk, `ASSERT_RESET, 1'd1, (^(dp2reg_d1_reg))); // spyglass disable W504 SelfDeterminedExpr-ML
// VCS coverage on
`endif
`undef ASSERT_RESET
`endif // ASSERT_ON
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass enable_block NoWidthInBasedNum-ML
// spyglass enable_block STARC-2.10.3.2a
// spyglass enable_block STARC05-2.1.3.1
// spyglass enable_block STARC-2.1.4.6
// spyglass enable_block W116
// spyglass enable_block W154
// spyglass enable_block W239
// spyglass enable_block W362
// spyglass enable_block WRN_58
// spyglass enable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
always @(posedge nvdla_core_clk or negedge nvdla_core_rstn) begin
if (!nvdla_core_rstn) begin
dp2reg_d1_nan_output_num <= {32{1'b0}};
end else begin
if ((dp2reg_d1_reg) == 1'b1) begin
dp2reg_d1_nan_output_num <= dp2reg_d1_nan_output_num_w;
// VCS coverage off
end else if ((dp2reg_d1_reg) == 1'b0) begin
end else begin
dp2reg_d1_nan_output_num <= 'bx; // spyglass disable STARC-2.10.1.6 W443 NoWidthInBasedNum-ML -- (Constant containing x or z used, Based number `bx contains an X, Width specification missing for based number)
// VCS coverage on
end
end
end
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass disable_block NoWidthInBasedNum-ML
// spyglass disable_block STARC-2.10.3.2a
// spyglass disable_block STARC05-2.1.3.1
// spyglass disable_block STARC-2.1.4.6
// spyglass disable_block W116
// spyglass disable_block W154
// spyglass disable_block W239
// spyglass disable_block W362
// spyglass disable_block WRN_58
// spyglass disable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
`ifdef ASSERT_ON
`ifdef FV_ASSERT_ON
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef SYNTHESIS
`define ASSERT_RESET nvdla_core_rstn
`else
`ifdef ASSERT_OFF_RESET_IS_X
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b0 : nvdla_core_rstn)
`else
`define ASSERT_RESET ((1'bx === nvdla_core_rstn) ? 1'b1 : nvdla_core_rstn)
`endif // ASSERT_OFF_RESET_IS_X
`endif // SYNTHESIS
`endif // FV_ASSERT_ON
`ifndef SYNTHESIS
// VCS coverage off
nv_assert_no_x #(0,1,0,"No X's allowed on control signals") zzz_assert_no_x_10x (nvdla_core_clk, `ASSERT_RESET, 1'd1, (^(dp2reg_d1_reg))); // spyglass disable W504 SelfDeterminedExpr-ML
// VCS coverage on
`endif
`undef ASSERT_RESET
`endif // ASSERT_ON
`ifdef SPYGLASS_ASSERT_ON
`else
// spyglass enable_block NoWidthInBasedNum-ML
// spyglass enable_block STARC-2.10.3.2a
// spyglass enable_block STARC05-2.1.3.1
// spyglass enable_block STARC-2.1.4.6
// spyglass enable_block W116
// spyglass enable_block W154
// spyglass enable_block W239
// spyglass enable_block W362
// spyglass enable_block WRN_58
// spyglass enable_block WRN_61
`endif // SPYGLASS_ASSERT_ON
endmodule // NV_NVDLA_PDP_reg