a2o/dev/verilog/work/mmq_perv.v

907 lines
30 KiB
Verilog

// © IBM Corp. 2020
// Licensed under the Apache License, Version 2.0 (the "License"), as modified by
// the terms below; you may not use the files in this repository except in
// compliance with the License as modified.
// You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0
//
// Modified Terms:
//
// 1) For the purpose of the patent license granted to you in Section 3 of the
// License, the "Work" hereby includes implementations of the work of authorship
// in physical form.
//
// 2) Notwithstanding any terms to the contrary in the License, any licenses
// necessary for implementation of the Work that are available from OpenPOWER
// via the Power ISA End User License Agreement (EULA) are explicitly excluded
// hereunder, and may be obtained from OpenPOWER under the terms and conditions
// of the EULA.
//
// Unless required by applicable law or agreed to in writing, the reference design
// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License
// for the specific language governing permissions and limitations under the License.
//
// Additional rights, including the ability to physically implement a softcore that
// is compliant with the required sections of the Power ISA Specification, are
// available at no cost under the terms of the OpenPOWER Power ISA EULA, which can be
// obtained (along with the Power ISA) here: https://openpowerfoundation.org.
// *********************************************************************
//
// This is the ENTITY for mmq_perv (pervasive logic)
//
// *********************************************************************
`timescale 1 ns / 1 ns
`include "tri_a2o.vh"
`include "mmu_a2o.vh"
module mmq_perv(
inout vdd,
inout gnd,
input clk,
input rst,
input [0:1] pc_mm_sg_3,
input [0:1] pc_mm_func_sl_thold_3,
input [0:1] pc_mm_func_slp_sl_thold_3,
input pc_mm_gptr_sl_thold_3,
input pc_mm_fce_3,
input pc_mm_time_sl_thold_3,
input pc_mm_repr_sl_thold_3,
input pc_mm_abst_sl_thold_3,
input pc_mm_abst_slp_sl_thold_3,
input pc_mm_cfg_sl_thold_3,
input pc_mm_cfg_slp_sl_thold_3,
input pc_mm_func_nsl_thold_3,
input pc_mm_func_slp_nsl_thold_3,
input pc_mm_ary_nsl_thold_3,
input pc_mm_ary_slp_nsl_thold_3,
input tc_ac_ccflush_dc,
input tc_scan_diag_dc,
input tc_ac_scan_dis_dc_b,
output [0:1] pc_sg_0,
output [0:1] pc_sg_1,
output [0:1] pc_sg_2,
output [0:1] pc_func_sl_thold_2,
output [0:1] pc_func_slp_sl_thold_2,
output pc_func_slp_nsl_thold_2,
output pc_cfg_sl_thold_2,
output pc_cfg_slp_sl_thold_2,
output pc_fce_2,
output pc_time_sl_thold_0,
output pc_repr_sl_thold_0,
output pc_abst_sl_thold_0,
output pc_abst_slp_sl_thold_0,
output pc_ary_nsl_thold_0,
output pc_ary_slp_nsl_thold_0,
output [0:1] pc_func_sl_thold_0,
output [0:1] pc_func_sl_thold_0_b,
output [0:1] pc_func_slp_sl_thold_0,
output [0:1] pc_func_slp_sl_thold_0_b,
output lcb_clkoff_dc_b,
output lcb_act_dis_dc,
output lcb_d_mode_dc,
output [0:4] lcb_delay_lclkr_dc,
output [0:4] lcb_mpw1_dc_b,
output lcb_mpw2_dc_b,
output g6t_gptr_lcb_clkoff_dc_b,
output g6t_gptr_lcb_act_dis_dc,
output g6t_gptr_lcb_d_mode_dc,
output [0:4] g6t_gptr_lcb_delay_lclkr_dc,
output [0:4] g6t_gptr_lcb_mpw1_dc_b,
output g6t_gptr_lcb_mpw2_dc_b,
output g8t_gptr_lcb_clkoff_dc_b,
output g8t_gptr_lcb_act_dis_dc,
output g8t_gptr_lcb_d_mode_dc,
output [0:4] g8t_gptr_lcb_delay_lclkr_dc,
output [0:4] g8t_gptr_lcb_mpw1_dc_b,
output g8t_gptr_lcb_mpw2_dc_b,
// abist engine controls for arrays from pervasive
input [0:3] pc_mm_abist_dcomp_g6t_2r,
input [0:3] pc_mm_abist_di_0,
input [0:3] pc_mm_abist_di_g6t_2r,
input pc_mm_abist_ena_dc,
input pc_mm_abist_g6t_r_wb,
input pc_mm_abist_g8t1p_renb_0,
input pc_mm_abist_g8t_bw_0,
input pc_mm_abist_g8t_bw_1,
input [0:3] pc_mm_abist_g8t_dcomp,
input pc_mm_abist_g8t_wenb,
input [0:9] pc_mm_abist_raddr_0,
input [0:9] pc_mm_abist_waddr_0,
input pc_mm_abist_wl128_comp_ena,
output pc_mm_abist_g8t_wenb_q,
output pc_mm_abist_g8t1p_renb_0_q,
output [0:3] pc_mm_abist_di_0_q,
output pc_mm_abist_g8t_bw_1_q,
output pc_mm_abist_g8t_bw_0_q,
output [0:9] pc_mm_abist_waddr_0_q,
output [0:9] pc_mm_abist_raddr_0_q,
output pc_mm_abist_wl128_comp_ena_q,
output [0:3] pc_mm_abist_g8t_dcomp_q,
output [0:3] pc_mm_abist_dcomp_g6t_2r_q,
output [0:3] pc_mm_abist_di_g6t_2r_q,
output pc_mm_abist_g6t_r_wb_q,
// BOLT-ON pervasive stuff for asic
input pc_mm_bolt_sl_thold_3,
input pc_mm_bo_enable_3, // general bolt-on enable
output pc_mm_bolt_sl_thold_0,
output pc_mm_bo_enable_2,
(* pin_data="PIN_FUNCTION=/SCAN_IN/" *)
input gptr_scan_in,
(* pin_data="PIN_FUNCTION=/SCAN_OUT/" *)
output gptr_scan_out,
(* pin_data="PIN_FUNCTION=/SCAN_IN/" *)
input time_scan_in,
output time_scan_in_int,
input time_scan_out_int,
(* pin_data="PIN_FUNCTION=/SCAN_OUT/" *)
output time_scan_out,
(* pin_data="PIN_FUNCTION=/SCAN_IN/" *)
input [0:9] func_scan_in,
output [0:9] func_scan_in_int,
input [0:9] func_scan_out_int,
(* pin_data="PIN_FUNCTION=/SCAN_OUT/" *)
output [0:9] func_scan_out,
(* pin_data="PIN_FUNCTION=/SCAN_IN/" *)
input repr_scan_in,
output repr_scan_in_int,
input repr_scan_out_int,
(* pin_data="PIN_FUNCTION=/SCAN_OUT/" *)
output repr_scan_out,
(* pin_data="PIN_FUNCTION=/SCAN_IN/" *)
input [0:1] abst_scan_in,
output [0:1] abst_scan_in_int,
input [0:1] abst_scan_out_int,
(* pin_data="PIN_FUNCTION=/SCAN_OUT/" *)
output [0:1] abst_scan_out,
(* pin_data="PIN_FUNCTION=/SCAN_IN/" *)
input bcfg_scan_in, // config latches that are setup same on all cores
output bcfg_scan_in_int,
input bcfg_scan_out_int,
(* pin_data="PIN_FUNCTION=/SCAN_OUT/" *)
output bcfg_scan_out,
(* pin_data="PIN_FUNCTION=/SCAN_IN/" *)
input ccfg_scan_in, // config latches that could be setup differently on multiple cores
output ccfg_scan_in_int,
input ccfg_scan_out_int,
(* pin_data="PIN_FUNCTION=/SCAN_OUT/" *)
output ccfg_scan_out,
(* pin_data="PIN_FUNCTION=/SCAN_IN/" *)
input dcfg_scan_in,
output dcfg_scan_in_int,
input dcfg_scan_out_int,
(* pin_data="PIN_FUNCTION=/SCAN_OUT/" *)
output dcfg_scan_out
);
wire tidn;
wire tiup;
wire [0:1] pc_func_sl_thold_2_int;
wire [0:1] pc_func_slp_sl_thold_2_int;
wire [0:1] pc_sg_2_int;
wire pc_gptr_sl_thold_2_int;
wire pc_fce_2_int;
wire pc_time_sl_thold_2_int;
wire pc_repr_sl_thold_2_int;
wire pc_abst_sl_thold_2_int;
wire pc_abst_slp_sl_thold_2_int;
wire pc_cfg_sl_thold_2_int;
wire pc_cfg_slp_sl_thold_2_int;
wire pc_func_nsl_thold_2_int;
wire pc_func_slp_nsl_thold_2_int;
wire pc_ary_nsl_thold_2_int;
wire pc_ary_slp_nsl_thold_2_int;
wire pc_mm_bolt_sl_thold_2_int;
wire [0:1] pc_func_sl_thold_1_int;
wire [0:1] pc_func_slp_sl_thold_1_int;
wire [0:1] pc_sg_1_int;
wire pc_gptr_sl_thold_1_int;
wire pc_fce_1_int;
wire pc_time_sl_thold_1_int;
wire pc_repr_sl_thold_1_int;
wire pc_abst_sl_thold_1_int;
wire pc_abst_slp_sl_thold_1_int;
wire pc_cfg_sl_thold_1_int;
wire pc_cfg_slp_sl_thold_1_int;
wire pc_func_nsl_thold_1_int;
wire pc_func_slp_nsl_thold_1_int;
wire pc_ary_nsl_thold_1_int;
wire pc_ary_slp_nsl_thold_1_int;
wire pc_mm_bolt_sl_thold_1_int;
wire [0:1] pc_func_sl_thold_0_int;
wire [0:1] pc_func_slp_sl_thold_0_int;
wire [0:1] pc_sg_0_int;
wire pc_gptr_sl_thold_0_int;
wire pc_fce_0_int;
wire pc_time_sl_thold_0_int;
wire pc_repr_sl_thold_0_int;
wire pc_abst_sl_thold_0_int;
wire pc_abst_slp_sl_thold_0_int;
wire pc_cfg_sl_thold_0_int;
wire pc_cfg_slp_sl_thold_0_int;
wire pc_func_nsl_thold_0_int;
wire pc_func_slp_nsl_thold_0_int;
wire pc_ary_nsl_thold_0_int;
wire pc_ary_slp_nsl_thold_0_int;
wire [0:1] pc_func_sl_thold_0_b_int;
wire [0:1] pc_func_slp_sl_thold_0_b_int;
wire [0:1] pc_func_slp_sl_force_int;
wire [0:1] pc_func_sl_force_int;
wire [0:1] abst_scan_in_q;
wire [0:1] abst_scan_out_q;
wire time_scan_in_q;
wire time_scan_out_q;
wire repr_scan_in_q;
wire repr_scan_out_q;
wire gptr_scan_in_q;
wire gptr_scan_out_int;
wire gptr_scan_out_q;
wire [0:1] gptr_scan_lcbctrl;
wire bcfg_scan_in_q;
wire bcfg_scan_out_q;
wire ccfg_scan_in_q;
wire ccfg_scan_out_q;
wire dcfg_scan_in_q;
wire dcfg_scan_out_q;
wire [0:9] func_scan_in_q;
wire [0:9] func_scan_out_q;
wire [0:1] slat_force;
wire abst_slat_thold_b;
wire abst_slat_d2clk;
//wire [0:`NCLK_WIDTH-1] abst_slat_lclk;
wire time_slat_thold_b;
wire time_slat_d2clk;
//wire [0:`NCLK_WIDTH-1] time_slat_lclk;
wire repr_slat_thold_b;
wire repr_slat_d2clk;
//wire [0:`NCLK_WIDTH-1] repr_slat_lclk;
wire gptr_slat_thold_b;
wire gptr_slat_d2clk;
//wire [0:`NCLK_WIDTH-1] gptr_slat_lclk;
wire bcfg_slat_thold_b;
wire bcfg_slat_d2clk;
//wire [0:`NCLK_WIDTH-1] bcfg_slat_lclk;
wire ccfg_slat_thold_b;
wire ccfg_slat_d2clk;
//wire [0:`NCLK_WIDTH-1] ccfg_slat_lclk;
wire dcfg_slat_thold_b;
wire dcfg_slat_d2clk;
//wire [0:`NCLK_WIDTH-1] dcfg_slat_lclk;
wire func_slat_thold_b;
wire func_slat_d2clk;
//wire [0:`NCLK_WIDTH-1] func_slat_lclk;
wire pc_abst_sl_thold_0_b;
wire pc_abst_sl_force;
wire [0:4] lcb_delay_lclkr_dc_int;
wire lcb_d_mode_dc_int;
wire [0:4] lcb_mpw1_dc_b_int;
wire lcb_mpw2_dc_b_int;
wire lcb_clkoff_dc_b_int;
wire [0:41] abist_siv;
wire [0:41] abist_sov;
(* analysis_not_referenced="true" *)
wire [0:8] unused_dc;
(* analysis_not_referenced="true" *)
wire [0:3] perv_abst_stg_q, perv_abst_stg_q_b;
(* analysis_not_referenced="true" *)
wire [0:1] perv_time_stg_q, perv_time_stg_q_b, perv_repr_stg_q, perv_repr_stg_q_b,
perv_gptr_stg_q, perv_gptr_stg_q_b, perv_bcfg_stg_q, perv_bcfg_stg_q_b,
perv_ccfg_stg_q, perv_ccfg_stg_q_b, perv_dcfg_stg_q, perv_dcfg_stg_q_b;
(* analysis_not_referenced="true" *)
wire [0:19] perv_func_stg_q, perv_func_stg_q_b;
assign tidn = 1'b0;
assign tiup = 1'b1;
tri_plat #(.WIDTH(20)) perv_3to2_reg(
.vd(vdd),
.gd(gnd),
.clk(clk),
.rst(rst),
.flush(tc_ac_ccflush_dc),
.din( {pc_mm_sg_3[0:1],
pc_mm_func_slp_sl_thold_3[0:1],
pc_mm_func_sl_thold_3[0:1],
pc_mm_gptr_sl_thold_3,
pc_mm_fce_3,
pc_mm_time_sl_thold_3,
pc_mm_repr_sl_thold_3,
pc_mm_abst_sl_thold_3,
pc_mm_abst_slp_sl_thold_3,
pc_mm_cfg_sl_thold_3,
pc_mm_cfg_slp_sl_thold_3,
pc_mm_func_nsl_thold_3,
pc_mm_func_slp_nsl_thold_3,
pc_mm_ary_nsl_thold_3,
pc_mm_ary_slp_nsl_thold_3,
pc_mm_bolt_sl_thold_3,
pc_mm_bo_enable_3} ),
.q( {pc_sg_2_int[0:1],
pc_func_slp_sl_thold_2_int[0:1],
pc_func_sl_thold_2_int[0:1],
pc_gptr_sl_thold_2_int,
pc_fce_2_int,
pc_time_sl_thold_2_int,
pc_repr_sl_thold_2_int,
pc_abst_sl_thold_2_int,
pc_abst_slp_sl_thold_2_int,
pc_cfg_sl_thold_2_int,
pc_cfg_slp_sl_thold_2_int,
pc_func_nsl_thold_2_int,
pc_func_slp_nsl_thold_2_int,
pc_ary_nsl_thold_2_int,
pc_ary_slp_nsl_thold_2_int,
pc_mm_bolt_sl_thold_2_int,
pc_mm_bo_enable_2} )
);
tri_plat #(.WIDTH(19)) perv_2to1_reg(
.vd(vdd),
.gd(gnd),
.clk(clk),
.rst(rst),
.flush(tc_ac_ccflush_dc),
.din( {pc_sg_2_int[0:1],
pc_func_slp_sl_thold_2_int[0:1],
pc_func_sl_thold_2_int[0:1],
pc_gptr_sl_thold_2_int,
pc_fce_2_int,
pc_time_sl_thold_2_int,
pc_repr_sl_thold_2_int,
pc_abst_sl_thold_2_int,
pc_abst_slp_sl_thold_2_int,
pc_cfg_sl_thold_2_int,
pc_cfg_slp_sl_thold_2_int,
pc_func_nsl_thold_2_int,
pc_func_slp_nsl_thold_2_int,
pc_ary_nsl_thold_2_int,
pc_ary_slp_nsl_thold_2_int,
pc_mm_bolt_sl_thold_2_int} ),
.q( {pc_sg_1_int[0:1],
pc_func_slp_sl_thold_1_int[0:1],
pc_func_sl_thold_1_int[0:1],
pc_gptr_sl_thold_1_int,
pc_fce_1_int,
pc_time_sl_thold_1_int,
pc_repr_sl_thold_1_int,
pc_abst_sl_thold_1_int,
pc_abst_slp_sl_thold_1_int,
pc_cfg_sl_thold_1_int,
pc_cfg_slp_sl_thold_1_int,
pc_func_nsl_thold_1_int,
pc_func_slp_nsl_thold_1_int,
pc_ary_nsl_thold_1_int,
pc_ary_slp_nsl_thold_1_int,
pc_mm_bolt_sl_thold_1_int} )
);
tri_plat #(.WIDTH(19)) perv_1to0_reg(
.vd(vdd),
.gd(gnd),
.clk(clk),
.rst(rst),
.flush(tc_ac_ccflush_dc),
.din( {pc_sg_1_int[0:1],
pc_func_slp_sl_thold_1_int[0:1],
pc_func_sl_thold_1_int[0:1],
pc_gptr_sl_thold_1_int,
pc_fce_1_int,
pc_time_sl_thold_1_int,
pc_repr_sl_thold_1_int,
pc_abst_sl_thold_1_int,
pc_abst_slp_sl_thold_1_int,
pc_cfg_sl_thold_1_int,
pc_cfg_slp_sl_thold_1_int,
pc_func_nsl_thold_1_int,
pc_func_slp_nsl_thold_1_int,
pc_ary_nsl_thold_1_int,
pc_ary_slp_nsl_thold_1_int,
pc_mm_bolt_sl_thold_1_int} ),
.q( {pc_sg_0_int[0:1],
pc_func_slp_sl_thold_0_int[0:1],
pc_func_sl_thold_0_int[0:1],
pc_gptr_sl_thold_0_int,
pc_fce_0_int,
pc_time_sl_thold_0_int,
pc_repr_sl_thold_0_int,
pc_abst_sl_thold_0_int,
pc_abst_slp_sl_thold_0_int,
pc_cfg_sl_thold_0_int,
pc_cfg_slp_sl_thold_0_int,
pc_func_nsl_thold_0_int,
pc_func_slp_nsl_thold_0_int,
pc_ary_nsl_thold_0_int,
pc_ary_slp_nsl_thold_0_int,
pc_mm_bolt_sl_thold_0} )
);
assign pc_time_sl_thold_0 = pc_time_sl_thold_0_int;
assign pc_abst_sl_thold_0 = pc_abst_sl_thold_0_int;
assign pc_abst_slp_sl_thold_0 = pc_abst_slp_sl_thold_0_int;
assign pc_repr_sl_thold_0 = pc_repr_sl_thold_0_int;
assign pc_ary_nsl_thold_0 = pc_ary_nsl_thold_0_int;
assign pc_ary_slp_nsl_thold_0 = pc_ary_slp_nsl_thold_0_int;
assign pc_func_sl_thold_0 = pc_func_sl_thold_0_int;
assign pc_func_sl_thold_0_b = pc_func_sl_thold_0_b_int;
assign pc_func_slp_sl_thold_0 = pc_func_slp_sl_thold_0_int;
assign pc_func_slp_sl_thold_0_b = pc_func_slp_sl_thold_0_b_int;
assign pc_sg_0 = pc_sg_0_int;
assign pc_sg_1 = pc_sg_1_int;
assign pc_sg_2 = pc_sg_2_int;
assign pc_func_sl_thold_2 = pc_func_sl_thold_2_int;
assign pc_func_slp_sl_thold_2 = pc_func_slp_sl_thold_2_int;
assign pc_func_slp_nsl_thold_2 = pc_func_slp_nsl_thold_2_int;
assign pc_cfg_sl_thold_2 = pc_cfg_sl_thold_2_int;
assign pc_cfg_slp_sl_thold_2 = pc_cfg_slp_sl_thold_2_int;
assign pc_fce_2 = pc_fce_2_int;
assign lcb_clkoff_dc_b = lcb_clkoff_dc_b_int;
assign lcb_d_mode_dc = lcb_d_mode_dc_int;
assign lcb_delay_lclkr_dc = lcb_delay_lclkr_dc_int;
assign lcb_mpw1_dc_b = lcb_mpw1_dc_b_int;
assign lcb_mpw2_dc_b = lcb_mpw2_dc_b_int;
tri_lcbcntl_mac perv_lcbctrl(
.vdd(vdd),
.gnd(gnd),
.sg(pc_sg_0_int[0]),
.clk(clk),
.rst(rst),
.scan_in(gptr_scan_in_q),
.scan_diag_dc(tc_scan_diag_dc),
.thold(pc_gptr_sl_thold_0_int),
.clkoff_dc_b(lcb_clkoff_dc_b_int),
.delay_lclkr_dc(lcb_delay_lclkr_dc_int[0:4]),
.act_dis_dc(unused_dc[6]),
.d_mode_dc(lcb_d_mode_dc_int),
.mpw1_dc_b(lcb_mpw1_dc_b_int[0:4]),
.mpw2_dc_b(lcb_mpw2_dc_b_int),
.scan_out(gptr_scan_lcbctrl[0])
);
tri_lcbcntl_array_mac perv_g6t_gptr_lcbctrl(
.vdd(vdd),
.gnd(gnd),
.sg(pc_sg_0_int[1]),
.clk(clk),
.rst(rst),
.scan_in(gptr_scan_lcbctrl[0]),
.scan_diag_dc(tc_scan_diag_dc),
.thold(pc_gptr_sl_thold_0_int),
.clkoff_dc_b(g6t_gptr_lcb_clkoff_dc_b),
.delay_lclkr_dc(g6t_gptr_lcb_delay_lclkr_dc[0:4]),
.act_dis_dc(unused_dc[7]),
.d_mode_dc(g6t_gptr_lcb_d_mode_dc),
.mpw1_dc_b(g6t_gptr_lcb_mpw1_dc_b[0:4]),
.mpw2_dc_b(g6t_gptr_lcb_mpw2_dc_b),
.scan_out(gptr_scan_lcbctrl[1])
);
tri_lcbcntl_array_mac perv_g8t_gptr_lcbctrl(
.vdd(vdd),
.gnd(gnd),
.sg(pc_sg_0_int[1]),
.clk(clk),
.rst(rst),
.scan_in(gptr_scan_lcbctrl[1]),
.scan_diag_dc(tc_scan_diag_dc),
.thold(pc_gptr_sl_thold_0_int),
.clkoff_dc_b(g8t_gptr_lcb_clkoff_dc_b),
.delay_lclkr_dc(g8t_gptr_lcb_delay_lclkr_dc[0:4]),
.act_dis_dc(unused_dc[8]),
.d_mode_dc(g8t_gptr_lcb_d_mode_dc),
.mpw1_dc_b(g8t_gptr_lcb_mpw1_dc_b[0:4]),
.mpw2_dc_b(g8t_gptr_lcb_mpw2_dc_b),
.scan_out(gptr_scan_out_int)
);
//never disable act pins, they are used functionally
assign lcb_act_dis_dc = 1'b0;
assign g8t_gptr_lcb_act_dis_dc = 1'b0;
assign g6t_gptr_lcb_act_dis_dc = 1'b0;
assign time_scan_in_int = time_scan_in_q;
assign repr_scan_in_int = repr_scan_in_q;
assign func_scan_in_int = func_scan_in_q;
assign bcfg_scan_in_int = bcfg_scan_in_q;
assign ccfg_scan_in_int = ccfg_scan_in_q;
assign dcfg_scan_in_int = dcfg_scan_in_q;
assign time_scan_out = time_scan_out_q & tc_ac_scan_dis_dc_b;
assign gptr_scan_out = gptr_scan_out_q & tc_ac_scan_dis_dc_b;
assign repr_scan_out = repr_scan_out_q & tc_ac_scan_dis_dc_b;
assign func_scan_out = func_scan_out_q & {10{tc_ac_scan_dis_dc_b}};
assign abst_scan_out = abst_scan_out_q & {2{tc_ac_scan_dis_dc_b}};
assign bcfg_scan_out = bcfg_scan_out_q & tc_ac_scan_dis_dc_b;
assign ccfg_scan_out = ccfg_scan_out_q & tc_ac_scan_dis_dc_b;
assign dcfg_scan_out = dcfg_scan_out_q & tc_ac_scan_dis_dc_b;
// LCBs for scan only staging latches
assign slat_force = pc_sg_0_int;
assign abst_slat_thold_b = (~pc_abst_sl_thold_0_int);
assign time_slat_thold_b = (~pc_time_sl_thold_0_int);
assign repr_slat_thold_b = (~pc_repr_sl_thold_0_int);
assign gptr_slat_thold_b = (~pc_gptr_sl_thold_0_int);
assign bcfg_slat_thold_b = (~pc_cfg_sl_thold_0_int);
assign ccfg_slat_thold_b = (~pc_cfg_sl_thold_0_int);
assign dcfg_slat_thold_b = (~pc_cfg_sl_thold_0_int);
assign func_slat_thold_b = (~pc_func_sl_thold_0_int[0]);
/*
tri_lcbs perv_lcbs_abst(
.vd(vdd),
.gd(gnd),
.delay_lclkr(lcb_delay_lclkr_dc_int[0]),
.clk(clk),
.rst(rst),
.force_t(slat_force[1]),
.thold_b(abst_slat_thold_b),
.dclk(abst_slat_d2clk),
.lclk(abst_slat_lclk)
);
*/
wire abst_slat_lclk;
assign abst_slat_lclk = 0;
assign abst_slat_d2clk = 0;
tri_slat_scan #(.WIDTH(4), .INIT(4'b0000)) perv_abst_stg(
.vd(vdd),
.gd(gnd),
.dclk(abst_slat_d2clk),
.lclk(abst_slat_lclk),
.scan_in( {abst_scan_out_int, abst_scan_in} ),
.scan_out( {abst_scan_out_q, abst_scan_in_q} ),
.q( perv_abst_stg_q),
.q_b( perv_abst_stg_q_b)
);
/*
tri_lcbs perv_lcbs_time(
.vd(vdd),
.gd(gnd),
.delay_lclkr(lcb_delay_lclkr_dc_int[0]),
.clk(clk),
.rst(rst),
.force_t(slat_force[1]),
.thold_b(time_slat_thold_b),
.dclk(time_slat_d2clk),
.lclk(time_slat_lclk)
);
*/
wire time_slat_lclk;
assign time_slat_lclk = 0;
assign time_slat_d2clk = 0;
tri_slat_scan #(.WIDTH(2), .INIT(2'b00)) perv_time_stg(
.vd(vdd),
.gd(gnd),
.dclk(time_slat_d2clk),
.lclk(time_slat_lclk),
.scan_in( {time_scan_in, time_scan_out_int} ),
.scan_out( {time_scan_in_q, time_scan_out_q} ),
.q( perv_time_stg_q),
.q_b( perv_time_stg_q_b)
);
/*
tri_lcbs perv_lcbs_repr(
.vd(vdd),
.gd(gnd),
.delay_lclkr(lcb_delay_lclkr_dc_int[0]),
.clk(clk),
.rst(rst),
.force_t(slat_force[1]),
.thold_b(repr_slat_thold_b),
.dclk(repr_slat_d2clk),
.lclk(repr_slat_lclk)
);
*/
wire repr_slat_lclk;
assign repr_slat_lclk = 0;
assign repr_slat_d2clk = 0;
tri_slat_scan #(.WIDTH(2), .INIT(2'b00)) perv_repr_stg(
.vd(vdd),
.gd(gnd),
.dclk(repr_slat_d2clk),
.lclk(repr_slat_lclk),
.scan_in( {repr_scan_in, repr_scan_out_int} ),
.scan_out( {repr_scan_in_q, repr_scan_out_q} ),
.q( perv_repr_stg_q),
.q_b( perv_repr_stg_q_b)
);
/*
tri_lcbs perv_lcbs_gptr(
.vd(vdd),
.gd(gnd),
.delay_lclkr(tiup),
.clk(clk),
.rst(rst),
.force_t(slat_force[0]),
.thold_b(gptr_slat_thold_b),
.dclk(gptr_slat_d2clk),
.lclk(gptr_slat_lclk)
);
*/
wire gptr_slat_lclk;
assign gptr_slat_lclk = 0;
assign gptr_slat_d2clk = 0;
tri_slat_scan #(.WIDTH(2), .INIT(2'b00)) perv_gptr_stg(
.vd(vdd),
.gd(gnd),
.dclk(gptr_slat_d2clk),
.lclk(gptr_slat_lclk),
.scan_in( {gptr_scan_in, gptr_scan_out_int} ),
.scan_out( {gptr_scan_in_q, gptr_scan_out_q} ),
.q( perv_gptr_stg_q),
.q_b( perv_gptr_stg_q_b)
);
/*
tri_lcbs perv_lcbs_bcfg(
.vd(vdd),
.gd(gnd),
.delay_lclkr(lcb_delay_lclkr_dc_int[0]),
.clk(clk),
.rst(rst),
.force_t(slat_force[0]),
.thold_b(bcfg_slat_thold_b),
.dclk(bcfg_slat_d2clk),
.lclk(bcfg_slat_lclk)
);
*/
wire bcfg_slat_lclk;
assign bcfg_slat_lclk = 0;
assign bcfg_slat_d2clk = 0;
tri_slat_scan #(.WIDTH(2), .INIT(2'b00)) perv_bcfg_stg(
.vd(vdd),
.gd(gnd),
.dclk(bcfg_slat_d2clk),
.lclk(bcfg_slat_lclk),
.scan_in( {bcfg_scan_in, bcfg_scan_out_int} ),
.scan_out( {bcfg_scan_in_q, bcfg_scan_out_q} ),
.q( perv_bcfg_stg_q),
.q_b( perv_bcfg_stg_q_b)
);
/*
tri_lcbs perv_lcbs_ccfg(
.vd(vdd),
.gd(gnd),
.delay_lclkr(lcb_delay_lclkr_dc_int[0]),
.clk(clk),
.rst(rst),
.force_t(slat_force[0]),
.thold_b(ccfg_slat_thold_b),
.dclk(ccfg_slat_d2clk),
.lclk(ccfg_slat_lclk)
);
*/
wire ccfg_slat_lclk;
assign ccfg_slat_lclk = 0;
assign ccfg_slat_d2clk = 0;
tri_slat_scan #(.WIDTH(2), .INIT(2'b00)) perv_ccfg_stg(
.vd(vdd),
.gd(gnd),
.dclk(ccfg_slat_d2clk),
.lclk(ccfg_slat_lclk),
.scan_in( {ccfg_scan_in, ccfg_scan_out_int} ),
.scan_out( {ccfg_scan_in_q, ccfg_scan_out_q} ),
.q( perv_ccfg_stg_q),
.q_b( perv_ccfg_stg_q_b)
);
/*
tri_lcbs perv_lcbs_dcfg(
.vd(vdd),
.gd(gnd),
.delay_lclkr(lcb_delay_lclkr_dc_int[0]),
.clk(clk),
.rst(rst),
.force_t(slat_force[0]),
.thold_b(dcfg_slat_thold_b),
.dclk(dcfg_slat_d2clk),
.lclk(dcfg_slat_lclk)
);
*/
wire dcfg_slat_lclk;
assign dcfg_slat_lclk = 0;
assign dcfg_slat_d2clk = 0;
tri_slat_scan #(.WIDTH(2), .INIT(2'b00)) perv_dcfg_stg(
.vd(vdd),
.gd(gnd),
.dclk(dcfg_slat_d2clk),
.lclk(dcfg_slat_lclk),
.scan_in( {dcfg_scan_in, dcfg_scan_out_int} ),
.scan_out( {dcfg_scan_in_q, dcfg_scan_out_q} ),
.q( perv_dcfg_stg_q),
.q_b( perv_dcfg_stg_q_b)
);
/*
tri_lcbs perv_lcbs_func(
.vd(vdd),
.gd(gnd),
.delay_lclkr(lcb_delay_lclkr_dc_int[0]),
.clk(clk),
.rst(rst),
.force_t(slat_force[0]),
.thold_b(func_slat_thold_b),
.dclk(func_slat_d2clk),
.lclk(func_slat_lclk)
);
*/
wire func_slat_lclk;
assign func_slat_lclk = 0;
assign func_slat_d2clk = 0;
tri_slat_scan #(.WIDTH(20), .INIT(20'b00000000000000000000)) perv_func_stg(
.vd(vdd),
.gd(gnd),
.dclk(func_slat_d2clk),
.lclk(func_slat_lclk),
.scan_in( {func_scan_out_int, func_scan_in} ),
.scan_out( {func_scan_out_q, func_scan_in_q} ),
.q( perv_func_stg_q),
.q_b( perv_func_stg_q_b)
);
tri_lcbor perv_lcbor_func_sl_0(
.clkoff_b(lcb_clkoff_dc_b_int),
.thold(pc_func_sl_thold_0_int[0]),
.sg(pc_sg_0_int[0]),
.act_dis(tidn),
.force_t(pc_func_sl_force_int[0]),
.thold_b(pc_func_sl_thold_0_b_int[0])
);
tri_lcbor perv_lcbor_func_sl_1(
.clkoff_b(lcb_clkoff_dc_b_int),
.thold(pc_func_sl_thold_0_int[1]),
.sg(pc_sg_0_int[1]),
.act_dis(tidn),
.force_t(pc_func_sl_force_int[1]),
.thold_b(pc_func_sl_thold_0_b_int[1])
);
tri_lcbor perv_lcbor_func_slp_sl_0(
.clkoff_b(lcb_clkoff_dc_b_int),
.thold(pc_func_slp_sl_thold_0_int[0]),
.sg(pc_sg_0_int[0]),
.act_dis(tidn),
.force_t(pc_func_slp_sl_force_int[0]),
.thold_b(pc_func_slp_sl_thold_0_b_int[0])
);
tri_lcbor perv_lcbor_func_slp_sl_1(
.clkoff_b(lcb_clkoff_dc_b_int),
.thold(pc_func_slp_sl_thold_0_int[1]),
.sg(pc_sg_0_int[1]),
.act_dis(tidn),
.force_t(pc_func_slp_sl_force_int[1]),
.thold_b(pc_func_slp_sl_thold_0_b_int[1])
);
tri_lcbor perv_lcbor_abst_sl(
.clkoff_b(lcb_clkoff_dc_b_int),
.thold(pc_abst_sl_thold_0_int),
.sg(pc_sg_0_int[1]),
.act_dis(tidn),
.force_t(pc_abst_sl_force),
.thold_b(pc_abst_sl_thold_0_b)
);
//---------------------------------------------------------------------
// abist latches
//---------------------------------------------------------------------
tri_rlmreg_p #(.INIT(0), .WIDTH(42), .NEEDS_SRESET(0)) abist_reg(
.vd(vdd),
.gd(gnd),
.clk(clk),
.rst(rst),
.act(pc_mm_abist_ena_dc),
.thold_b(pc_abst_sl_thold_0_b),
.sg(pc_sg_0_int[1]),
.force_t(pc_abst_sl_force),
.delay_lclkr(lcb_delay_lclkr_dc_int[0]),
.mpw1_b(lcb_mpw1_dc_b_int[0]),
.mpw2_b(lcb_mpw2_dc_b_int),
.d_mode(lcb_d_mode_dc_int),
.scin(abist_siv[0:41]),
.scout(abist_sov[0:41]),
.din( {pc_mm_abist_g8t_wenb,
pc_mm_abist_g8t1p_renb_0,
pc_mm_abist_di_0,
pc_mm_abist_g8t_bw_1,
pc_mm_abist_g8t_bw_0,
pc_mm_abist_waddr_0,
pc_mm_abist_raddr_0,
pc_mm_abist_wl128_comp_ena,
pc_mm_abist_g8t_dcomp,
pc_mm_abist_dcomp_g6t_2r,
pc_mm_abist_di_g6t_2r,
pc_mm_abist_g6t_r_wb} ),
.dout( {pc_mm_abist_g8t_wenb_q,
pc_mm_abist_g8t1p_renb_0_q,
pc_mm_abist_di_0_q,
pc_mm_abist_g8t_bw_1_q,
pc_mm_abist_g8t_bw_0_q,
pc_mm_abist_waddr_0_q,
pc_mm_abist_raddr_0_q,
pc_mm_abist_wl128_comp_ena_q,
pc_mm_abist_g8t_dcomp_q,
pc_mm_abist_dcomp_g6t_2r_q,
pc_mm_abist_di_g6t_2r_q,
pc_mm_abist_g6t_r_wb_q} )
);
assign abist_siv = {abist_sov[1:41], abst_scan_in_q[0]};
assign abst_scan_in_int[0] = abist_sov[0];
assign abst_scan_in_int[1] = abst_scan_in_q[1];
// unused spare signal assignments
assign unused_dc[0] = pc_fce_0_int;
assign unused_dc[1] = pc_cfg_slp_sl_thold_0_int;
assign unused_dc[2] = pc_func_nsl_thold_0_int;
assign unused_dc[3] = pc_func_slp_nsl_thold_0_int;
assign unused_dc[4] = |(pc_func_sl_force_int);
assign unused_dc[5] = |(pc_func_slp_sl_force_int);
endmodule