Module Definition
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Module Instance : tb.dut.u_reg.u_wkup_count_hi_cdc

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
92.86 100.00 71.43 100.00 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
84.89 94.74 75.00 89.83 80.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
100.00 100.00 100.00 100.00 100.00 u_reg


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_arb 75.16 92.86 71.74 86.05 50.00
u_src_to_dst_req 100.00 100.00 100.00 100.00 100.00



Module Instance : tb.dut.u_reg.u_wkup_ctrl_cdc

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
97.73 100.00 90.91 100.00 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
99.17 100.00 96.67 100.00 100.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
100.00 100.00 100.00 100.00 100.00 u_reg


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_arb 100.00 100.00 100.00 100.00 100.00
u_src_to_dst_req 100.00 100.00 100.00 100.00 100.00



Module Instance : tb.dut.u_reg.u_wkup_thold_hi_cdc

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
97.73 100.00 90.91 100.00 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
99.17 100.00 96.67 100.00 100.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
100.00 100.00 100.00 100.00 100.00 u_reg


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_arb 100.00 100.00 100.00 100.00 100.00
u_src_to_dst_req 100.00 100.00 100.00 100.00 100.00



Module Instance : tb.dut.u_reg.u_wkup_thold_lo_cdc

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
97.73 100.00 90.91 100.00 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
99.17 100.00 96.67 100.00 100.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
100.00 100.00 100.00 100.00 100.00 u_reg


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_arb 100.00 100.00 100.00 100.00 100.00
u_src_to_dst_req 100.00 100.00 100.00 100.00 100.00



Module Instance : tb.dut.u_reg.u_wdog_ctrl_cdc

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
97.73 100.00 90.91 100.00 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
99.17 100.00 96.67 100.00 100.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
100.00 100.00 100.00 100.00 100.00 u_reg


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_arb 100.00 100.00 100.00 100.00 100.00
u_src_to_dst_req 100.00 100.00 100.00 100.00 100.00



Module Instance : tb.dut.u_reg.u_wdog_bark_thold_cdc

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
97.73 100.00 90.91 100.00 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
99.17 100.00 96.67 100.00 100.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
100.00 100.00 100.00 100.00 100.00 u_reg


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_arb 100.00 100.00 100.00 100.00 100.00
u_src_to_dst_req 100.00 100.00 100.00 100.00 100.00



Module Instance : tb.dut.u_reg.u_wdog_bite_thold_cdc

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
97.73 100.00 90.91 100.00 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
99.17 100.00 96.67 100.00 100.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
100.00 100.00 100.00 100.00 100.00 u_reg


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_arb 100.00 100.00 100.00 100.00 100.00
u_src_to_dst_req 100.00 100.00 100.00 100.00 100.00



Module Instance : tb.dut.u_reg.u_wkup_count_lo_cdc

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
98.21 100.00 92.86 100.00 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
98.11 100.00 94.12 98.31 100.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
100.00 100.00 100.00 100.00 100.00 u_reg


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_arb 97.79 100.00 93.48 97.67 100.00
u_src_to_dst_req 100.00 100.00 100.00 100.00 100.00



Module Instance : tb.dut.u_reg.u_wdog_count_cdc

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
98.21 100.00 92.86 100.00 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
98.11 100.00 94.12 98.31 100.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
100.00 100.00 100.00 100.00 100.00 u_reg


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_arb 97.79 100.00 93.48 97.67 100.00
u_src_to_dst_req 100.00 100.00 100.00 100.00 100.00



Module Instance : tb.dut.u_reg.u_wkup_cause_cdc

Instance :
SCORELINECONDTOGGLEFSMBRANCHASSERT
98.44 100.00 93.75 100.00 100.00


Instance's subtree :
SCORELINECONDTOGGLEFSMBRANCHASSERT
98.15 100.00 94.29 98.31 100.00


Parent :
SCORELINECONDTOGGLEFSMBRANCHASSERTNAME
100.00 100.00 100.00 100.00 100.00 u_reg


Subtrees :
NAMESCORELINECONDTOGGLEFSMBRANCHASSERT
u_arb 97.79 100.00 93.48 97.67 100.00
u_src_to_dst_req 100.00 100.00 100.00 100.00 100.00

Line Coverage for Module : prim_reg_cdc
Line No.TotalCoveredPercent
TOTAL2222100.00
CONT_ASSIGN6511100.00
ALWAYS7166100.00
CONT_ASSIGN8511100.00
CONT_ASSIGN10911100.00
ALWAYS11599100.00
CONT_ASSIGN15011100.00
CONT_ASSIGN15511100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN20011100.00

64 65 1/1 assign src_req = src_we_i | src_re_i; Tests: T1 T2 T3  66 67 // busy indication back-pressures upstream if the register is accessed 68 // again. The busy indication is also used as a "commit" indication for 69 // resolving software and hardware write conflicts 70 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 71 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  72 1/1 src_busy_q <= '0; Tests: T1 T2 T3  73 1/1 end else if (src_req) begin Tests: T1 T2 T3  74 1/1 src_busy_q <= 1'b1; Tests: T1 T2 T3  75 1/1 end else if (src_ack) begin Tests: T1 T2 T3  76 1/1 src_busy_q <= 1'b0; Tests: T1 T2 T3  77 end MISSING_ELSE 78 end 79 80 // A src_ack should only be sent if there was a src_req. 81 // src_busy_q asserts whenever there is a src_req. By association, 82 // whenever src_ack is seen, then src_busy must be high. 83 `ASSERT(SrcAckBusyChk_A, src_ack |-> src_busy_q, clk_src_i, !rst_src_ni) 84 85 1/1 assign src_busy_o = src_busy_q; Tests: T1 T2 T3  86 87 // src_q acts as both the write holding register and the software read back 88 // register. 89 // When software performs a write, the write data is captured in src_q for 90 // CDC purposes. When not performing a write, the src_q reflects the most recent 91 // hardware value. For registers with no hardware access, this is simply the 92 // the value programmed by software (or in the case R1C, W1C etc) the value after 93 // the operation. For registers with hardware access, this reflects a potentially 94 // delayed version of the real value, as the software facing updates lag real 95 // time updates. 96 // 97 // To resolve software and hardware conflicts, the process is as follows: 98 // When software issues a write, this module asserts "busy". While busy, 99 // src_q does not take on destination value updates. Since the 100 // logic has committed to updating based on software command, there is an irreversible 101 // window from which hardware writes are ignored. Once the busy window completes, 102 // the cdc portion then begins sampling once more. 103 // 104 // This is consistent with prim_subreg_arb where during software / hardware conflicts, 105 // software is always prioritized. The main difference is the conflict resolution window 106 // is now larger instead of just one destination clock cycle. 107 108 logic busy; 109 1/1 assign busy = src_busy_q & !src_ack; Tests: T1 T2 T3  110 111 // This is the current destination value 112 logic [DataWidth-1:0] dst_qs; 113 logic src_update; 114 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 115 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  116 1/1 src_q <= ResetVal; Tests: T1 T2 T3  117 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  118 1/1 end else if (src_req) begin Tests: T1 T2 T3  119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 1/1 src_q <= src_wd_i & BitMask; Tests: T1 T2 T3  124 1/1 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; Tests: T1 T2 T3  125 1/1 end else if (src_busy_q && src_ack || src_update && !busy) begin Tests: T1 T2 T3  126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 1/1 src_q <= dst_qs; Tests: T1 T2 T3  135 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  136 end MISSING_ELSE 137 end 138 139 // The current design (tlul_adapter_reg) does not spit out a request if the destination it chooses 140 // (decoded from address) is busy. So this creates a situation in the current design where 141 // src_req_i and busy can never be high at the same time. 142 // While the code above could be coded directly to be expressed as `src_req & !busy`, which makes 143 // the intent clearer, it ends up causing coverage holes from the tool's perspective since that 144 // condition cannot be met. 145 // Thus we add an assertion here to ensure the condition is always satisfied. 146 `ASSERT(BusySrcReqChk_A, busy |-> !src_req, clk_src_i, !rst_src_ni) 147 148 // reserved bits are not used 149 logic unused_wd; 150 1/1 assign unused_wd = ^src_wd_i; Tests: T1 T2 T3  151 152 // src_q is always updated in the clk_src domain. 153 // when performing an update to the destination domain, it is guaranteed 154 // to not change by protocol. 155 1/1 assign src_qs_o = src_q; Tests: T1 T2 T3  156 1/1 assign dst_wd_o = src_q; Tests: T1 T2 T3  157 158 //////////////////////////// 159 // CDC handling 160 //////////////////////////// 161 162 logic dst_req_from_src; 163 logic dst_req; 164 165 166 // the software transaction is pulse synced across the domain. 167 // the prim_reg_cdc_arb module handles conflicts with ongoing hardware updates. 168 prim_pulse_sync u_src_to_dst_req ( 169 .clk_src_i, 170 .rst_src_ni, 171 .clk_dst_i, 172 .rst_dst_ni, 173 .src_pulse_i(src_req), 174 .dst_pulse_o(dst_req_from_src) 175 ); 176 177 prim_reg_cdc_arb #( 178 .DataWidth(DataWidth), 179 .ResetVal(ResetVal), 180 .DstWrReq(DstWrReq) 181 ) u_arb ( 182 .clk_src_i, 183 .rst_src_ni, 184 .clk_dst_i, 185 .rst_dst_ni, 186 .src_ack_o(src_ack), 187 .src_update_o(src_update), 188 .dst_req_i(dst_req_from_src), 189 .dst_req_o(dst_req), 190 .dst_update_i, 191 .dst_ds_i, 192 .dst_qs_i, 193 .dst_qs_o(dst_qs) 194 ); 195 196 197 // Each is valid only when destination request pulse is high; this is important in not propagating 198 // the internal assertion of 'dst_req' by the 'prim_pulse_sync' channel when just one domain is 199 // reset. 200 1/1 assign {dst_we_o, dst_re_o, dst_regwen_o} = txn_bits_q & {TxnWidth{dst_req}}; Tests: T1 T2 T3 

Cond Coverage for Module : prim_reg_cdc ( parameter DataWidth=13,ResetVal=0,BitMask=8191,DstWrReq=0,TxnWidth=3 + DataWidth=32,ResetVal=0,BitMask=-1,DstWrReq=0,TxnWidth=3 + DataWidth=32,ResetVal=0,BitMask=-1,DstWrReq=1,TxnWidth=3 + DataWidth=2,ResetVal=0,BitMask=3,DstWrReq=0,TxnWidth=3 )
Cond Coverage for Module self-instances :
SCORECOND
97.73 90.91
tb.dut.u_reg.u_wkup_ctrl_cdc

SCORECOND
97.73 90.91
tb.dut.u_reg.u_wkup_thold_hi_cdc

SCORECOND
97.73 90.91
tb.dut.u_reg.u_wkup_thold_lo_cdc

SCORECOND
97.73 90.91
tb.dut.u_reg.u_wdog_bark_thold_cdc

SCORECOND
97.73 90.91
tb.dut.u_reg.u_wdog_bite_thold_cdc

SCORECOND
92.86 71.43
tb.dut.u_reg.u_wkup_count_hi_cdc

SCORECOND
98.21 92.86
tb.dut.u_reg.u_wkup_count_lo_cdc

SCORECOND
98.21 92.86
tb.dut.u_reg.u_wdog_count_cdc

SCORECOND
97.73 90.91
tb.dut.u_reg.u_wdog_ctrl_cdc

TotalCoveredPercent
Conditions141392.86
Logical141392.86
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01CoveredT1,T2,T3
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT5,T7,T8
11CoveredT1,T2,T3

Cond Coverage for Module : prim_reg_cdc ( parameter DataWidth=1,ResetVal=0,BitMask=1,DstWrReq=1,TxnWidth=3 )
Cond Coverage for Module self-instances :
SCORECOND
98.44 93.75
tb.dut.u_reg.u_wkup_cause_cdc

TotalCoveredPercent
Conditions161593.75
Logical161593.75
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       123
 EXPRESSION (src_wd_i & BitMask)
             ----1---   ---2---
-1--2-StatusTests
0-CoveredT1,T2,T3
1-CoveredT38,T39,T40

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01CoveredT1,T2,T3
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT7,T36,T37
11CoveredT1,T2,T3

Branch Coverage for Module : prim_reg_cdc
Line No.TotalCoveredPercent
Branches 8 8 100.00
IF 71 4 4 100.00
IF 115 4 4 100.00


71 if (!rst_src_ni) begin -1- 72 src_busy_q <= '0; ==> 73 end else if (src_req) begin -2- 74 src_busy_q <= 1'b1; ==> 75 end else if (src_ack) begin -3- 76 src_busy_q <= 1'b0; ==> 77 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


115 if (!rst_src_ni) begin -1- 116 src_q <= ResetVal; ==> 117 txn_bits_q <= '0; 118 end else if (src_req) begin -2- 119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 src_q <= src_wd_i & BitMask; ==> 124 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; 125 end else if (src_busy_q && src_ack || src_update && !busy) begin -3- 126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 src_q <= dst_qs; ==> 135 txn_bits_q <= '0; 136 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


Assert Coverage for Module : prim_reg_cdc
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 4 4 100.00 4 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 4 4 100.00 4 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
BusySrcReqChk_A 2147483647 32537600 0 0
DstReqKnown_A 24048040 23149840 0 0
SrcAckBusyChk_A 2147483647 33700 0 0
SrcBusyKnown_A 2147483647 2147483647 0 0


BusySrcReqChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2147483647 32537600 0 0
T1 113250 4834 0 0
T2 223490 15325 0 0
T3 147390 8317 0 0
T4 644500 11398 0 0
T5 390100 26793 0 0
T6 577590 22169 0 0
T7 2874040 73403 0 0
T8 233800 19146 0 0
T9 0 5628 0 0
T10 0 25808 0 0
T11 845400 0 0 0
T12 1026830 0 0 0

DstReqKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 24048040 23149840 0 0
T1 970 230 0 0
T2 900 250 0 0
T3 1160 280 0 0
T4 3290 2460 0 0
T5 830 140 0 0
T6 1180 220 0 0
T7 23940 18290 0 0
T8 920 210 0 0
T11 8040 120 0 0
T12 17100 530 0 0

SrcAckBusyChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2147483647 33700 0 0
T1 113250 14 0 0
T2 223490 18 0 0
T3 147390 18 0 0
T4 644500 16 0 0
T5 390100 15 0 0
T6 577590 15 0 0
T7 2874040 166 0 0
T8 233800 18 0 0
T9 0 14 0 0
T10 0 14 0 0
T11 845400 0 0 0
T12 1026830 0 0 0

SrcBusyKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2147483647 2147483647 0 0
T1 113250 112300 0 0
T2 223490 222680 0 0
T3 147390 146780 0 0
T4 644500 643910 0 0
T5 390100 389590 0 0
T6 577590 577070 0 0
T7 2874040 2868800 0 0
T8 233800 232880 0 0
T11 845400 837900 0 0
T12 1026830 1010110 0 0

Line Coverage for Instance : tb.dut.u_reg.u_wkup_count_hi_cdc
Line No.TotalCoveredPercent
TOTAL2222100.00
CONT_ASSIGN6511100.00
ALWAYS7166100.00
CONT_ASSIGN8511100.00
CONT_ASSIGN10911100.00
ALWAYS11599100.00
CONT_ASSIGN15011100.00
CONT_ASSIGN15511100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN20011100.00

64 65 1/1 assign src_req = src_we_i | src_re_i; Tests: T1 T2 T3  66 67 // busy indication back-pressures upstream if the register is accessed 68 // again. The busy indication is also used as a "commit" indication for 69 // resolving software and hardware write conflicts 70 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 71 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  72 1/1 src_busy_q <= '0; Tests: T1 T2 T3  73 1/1 end else if (src_req) begin Tests: T1 T2 T3  74 1/1 src_busy_q <= 1'b1; Tests: T1 T2 T3  75 1/1 end else if (src_ack) begin Tests: T1 T2 T3  76 1/1 src_busy_q <= 1'b0; Tests: T1 T2 T3  77 end MISSING_ELSE 78 end 79 80 // A src_ack should only be sent if there was a src_req. 81 // src_busy_q asserts whenever there is a src_req. By association, 82 // whenever src_ack is seen, then src_busy must be high. 83 `ASSERT(SrcAckBusyChk_A, src_ack |-> src_busy_q, clk_src_i, !rst_src_ni) 84 85 1/1 assign src_busy_o = src_busy_q; Tests: T1 T2 T3  86 87 // src_q acts as both the write holding register and the software read back 88 // register. 89 // When software performs a write, the write data is captured in src_q for 90 // CDC purposes. When not performing a write, the src_q reflects the most recent 91 // hardware value. For registers with no hardware access, this is simply the 92 // the value programmed by software (or in the case R1C, W1C etc) the value after 93 // the operation. For registers with hardware access, this reflects a potentially 94 // delayed version of the real value, as the software facing updates lag real 95 // time updates. 96 // 97 // To resolve software and hardware conflicts, the process is as follows: 98 // When software issues a write, this module asserts "busy". While busy, 99 // src_q does not take on destination value updates. Since the 100 // logic has committed to updating based on software command, there is an irreversible 101 // window from which hardware writes are ignored. Once the busy window completes, 102 // the cdc portion then begins sampling once more. 103 // 104 // This is consistent with prim_subreg_arb where during software / hardware conflicts, 105 // software is always prioritized. The main difference is the conflict resolution window 106 // is now larger instead of just one destination clock cycle. 107 108 logic busy; 109 1/1 assign busy = src_busy_q & !src_ack; Tests: T1 T2 T3  110 111 // This is the current destination value 112 logic [DataWidth-1:0] dst_qs; 113 logic src_update; 114 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 115 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  116 1/1 src_q <= ResetVal; Tests: T1 T2 T3  117 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  118 1/1 end else if (src_req) begin Tests: T1 T2 T3  119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 1/1 src_q <= src_wd_i & BitMask; Tests: T1 T2 T3  124 1/1 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; Tests: T1 T2 T3  125 1/1 end else if (src_busy_q && src_ack || src_update && !busy) begin Tests: T1 T2 T3  126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 1/1 src_q <= dst_qs; Tests: T1 T2 T3  135 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  136 end MISSING_ELSE 137 end 138 139 // The current design (tlul_adapter_reg) does not spit out a request if the destination it chooses 140 // (decoded from address) is busy. So this creates a situation in the current design where 141 // src_req_i and busy can never be high at the same time. 142 // While the code above could be coded directly to be expressed as `src_req & !busy`, which makes 143 // the intent clearer, it ends up causing coverage holes from the tool's perspective since that 144 // condition cannot be met. 145 // Thus we add an assertion here to ensure the condition is always satisfied. 146 `ASSERT(BusySrcReqChk_A, busy |-> !src_req, clk_src_i, !rst_src_ni) 147 148 // reserved bits are not used 149 logic unused_wd; 150 1/1 assign unused_wd = ^src_wd_i; Tests: T1 T2 T3  151 152 // src_q is always updated in the clk_src domain. 153 // when performing an update to the destination domain, it is guaranteed 154 // to not change by protocol. 155 1/1 assign src_qs_o = src_q; Tests: T1 T2 T3  156 1/1 assign dst_wd_o = src_q; Tests: T1 T2 T3  157 158 //////////////////////////// 159 // CDC handling 160 //////////////////////////// 161 162 logic dst_req_from_src; 163 logic dst_req; 164 165 166 // the software transaction is pulse synced across the domain. 167 // the prim_reg_cdc_arb module handles conflicts with ongoing hardware updates. 168 prim_pulse_sync u_src_to_dst_req ( 169 .clk_src_i, 170 .rst_src_ni, 171 .clk_dst_i, 172 .rst_dst_ni, 173 .src_pulse_i(src_req), 174 .dst_pulse_o(dst_req_from_src) 175 ); 176 177 prim_reg_cdc_arb #( 178 .DataWidth(DataWidth), 179 .ResetVal(ResetVal), 180 .DstWrReq(DstWrReq) 181 ) u_arb ( 182 .clk_src_i, 183 .rst_src_ni, 184 .clk_dst_i, 185 .rst_dst_ni, 186 .src_ack_o(src_ack), 187 .src_update_o(src_update), 188 .dst_req_i(dst_req_from_src), 189 .dst_req_o(dst_req), 190 .dst_update_i, 191 .dst_ds_i, 192 .dst_qs_i, 193 .dst_qs_o(dst_qs) 194 ); 195 196 197 // Each is valid only when destination request pulse is high; this is important in not propagating 198 // the internal assertion of 'dst_req' by the 'prim_pulse_sync' channel when just one domain is 199 // reset. 200 1/1 assign {dst_we_o, dst_re_o, dst_regwen_o} = txn_bits_q & {TxnWidth{dst_req}}; Tests: T1 T2 T3 

Cond Coverage for Instance : tb.dut.u_reg.u_wkup_count_hi_cdc
TotalCoveredPercent
Conditions141071.43
Logical141071.43
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01Not Covered
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10Not Covered
11Not Covered

Branch Coverage for Instance : tb.dut.u_reg.u_wkup_count_hi_cdc
Line No.TotalCoveredPercent
Branches 8 8 100.00
IF 71 4 4 100.00
IF 115 4 4 100.00


71 if (!rst_src_ni) begin -1- 72 src_busy_q <= '0; ==> 73 end else if (src_req) begin -2- 74 src_busy_q <= 1'b1; ==> 75 end else if (src_ack) begin -3- 76 src_busy_q <= 1'b0; ==> 77 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


115 if (!rst_src_ni) begin -1- 116 src_q <= ResetVal; ==> 117 txn_bits_q <= '0; 118 end else if (src_req) begin -2- 119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 src_q <= src_wd_i & BitMask; ==> 124 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; 125 end else if (src_busy_q && src_ack || src_update && !busy) begin -3- 126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 src_q <= dst_qs; ==> 135 txn_bits_q <= '0; 136 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


Assert Coverage for Instance : tb.dut.u_reg.u_wkup_count_hi_cdc
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 4 4 100.00 4 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 4 4 100.00 4 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
BusySrcReqChk_A 622911264 4105650 0 0
DstReqKnown_A 2404804 2314984 0 0
SrcAckBusyChk_A 622911264 4284 0 0
SrcBusyKnown_A 622911264 622684546 0 0


BusySrcReqChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 4105650 0 0
T1 11325 721 0 0
T2 22349 2677 0 0
T3 14739 1395 0 0
T4 64450 1456 0 0
T5 39010 3140 0 0
T6 57759 2894 0 0
T7 287404 10647 0 0
T8 23380 3232 0 0
T9 0 734 0 0
T10 0 3345 0 0
T11 84540 0 0 0
T12 102683 0 0 0

DstReqKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2404804 2314984 0 0
T1 97 23 0 0
T2 90 25 0 0
T3 116 28 0 0
T4 329 246 0 0
T5 83 14 0 0
T6 118 22 0 0
T7 2394 1829 0 0
T8 92 21 0 0
T11 804 12 0 0
T12 1710 53 0 0

SrcAckBusyChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 4284 0 0
T1 11325 2 0 0
T2 22349 3 0 0
T3 14739 3 0 0
T4 64450 2 0 0
T5 39010 2 0 0
T6 57759 2 0 0
T7 287404 25 0 0
T8 23380 3 0 0
T9 0 2 0 0
T10 0 2 0 0
T11 84540 0 0 0
T12 102683 0 0 0

SrcBusyKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 622684546 0 0
T1 11325 11230 0 0
T2 22349 22268 0 0
T3 14739 14678 0 0
T4 64450 64391 0 0
T5 39010 38959 0 0
T6 57759 57707 0 0
T7 287404 286880 0 0
T8 23380 23288 0 0
T11 84540 83790 0 0
T12 102683 101011 0 0

Line Coverage for Instance : tb.dut.u_reg.u_wkup_ctrl_cdc
Line No.TotalCoveredPercent
TOTAL2222100.00
CONT_ASSIGN6511100.00
ALWAYS7166100.00
CONT_ASSIGN8511100.00
CONT_ASSIGN10911100.00
ALWAYS11599100.00
CONT_ASSIGN15011100.00
CONT_ASSIGN15511100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN20011100.00

64 65 1/1 assign src_req = src_we_i | src_re_i; Tests: T1 T2 T3  66 67 // busy indication back-pressures upstream if the register is accessed 68 // again. The busy indication is also used as a "commit" indication for 69 // resolving software and hardware write conflicts 70 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 71 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  72 1/1 src_busy_q <= '0; Tests: T1 T2 T3  73 1/1 end else if (src_req) begin Tests: T1 T2 T3  74 1/1 src_busy_q <= 1'b1; Tests: T1 T2 T3  75 1/1 end else if (src_ack) begin Tests: T1 T2 T3  76 1/1 src_busy_q <= 1'b0; Tests: T1 T2 T3  77 end MISSING_ELSE 78 end 79 80 // A src_ack should only be sent if there was a src_req. 81 // src_busy_q asserts whenever there is a src_req. By association, 82 // whenever src_ack is seen, then src_busy must be high. 83 `ASSERT(SrcAckBusyChk_A, src_ack |-> src_busy_q, clk_src_i, !rst_src_ni) 84 85 1/1 assign src_busy_o = src_busy_q; Tests: T1 T2 T3  86 87 // src_q acts as both the write holding register and the software read back 88 // register. 89 // When software performs a write, the write data is captured in src_q for 90 // CDC purposes. When not performing a write, the src_q reflects the most recent 91 // hardware value. For registers with no hardware access, this is simply the 92 // the value programmed by software (or in the case R1C, W1C etc) the value after 93 // the operation. For registers with hardware access, this reflects a potentially 94 // delayed version of the real value, as the software facing updates lag real 95 // time updates. 96 // 97 // To resolve software and hardware conflicts, the process is as follows: 98 // When software issues a write, this module asserts "busy". While busy, 99 // src_q does not take on destination value updates. Since the 100 // logic has committed to updating based on software command, there is an irreversible 101 // window from which hardware writes are ignored. Once the busy window completes, 102 // the cdc portion then begins sampling once more. 103 // 104 // This is consistent with prim_subreg_arb where during software / hardware conflicts, 105 // software is always prioritized. The main difference is the conflict resolution window 106 // is now larger instead of just one destination clock cycle. 107 108 logic busy; 109 1/1 assign busy = src_busy_q & !src_ack; Tests: T1 T2 T3  110 111 // This is the current destination value 112 logic [DataWidth-1:0] dst_qs; 113 logic src_update; 114 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 115 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  116 1/1 src_q <= ResetVal; Tests: T1 T2 T3  117 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  118 1/1 end else if (src_req) begin Tests: T1 T2 T3  119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 1/1 src_q <= src_wd_i & BitMask; Tests: T1 T2 T3  124 1/1 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; Tests: T1 T2 T3  125 1/1 end else if (src_busy_q && src_ack || src_update && !busy) begin Tests: T1 T2 T3  126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 1/1 src_q <= dst_qs; Tests: T1 T2 T3  135 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  136 end MISSING_ELSE 137 end 138 139 // The current design (tlul_adapter_reg) does not spit out a request if the destination it chooses 140 // (decoded from address) is busy. So this creates a situation in the current design where 141 // src_req_i and busy can never be high at the same time. 142 // While the code above could be coded directly to be expressed as `src_req & !busy`, which makes 143 // the intent clearer, it ends up causing coverage holes from the tool's perspective since that 144 // condition cannot be met. 145 // Thus we add an assertion here to ensure the condition is always satisfied. 146 `ASSERT(BusySrcReqChk_A, busy |-> !src_req, clk_src_i, !rst_src_ni) 147 148 // reserved bits are not used 149 logic unused_wd; 150 1/1 assign unused_wd = ^src_wd_i; Tests: T1 T2 T3  151 152 // src_q is always updated in the clk_src domain. 153 // when performing an update to the destination domain, it is guaranteed 154 // to not change by protocol. 155 1/1 assign src_qs_o = src_q; Tests: T1 T2 T3  156 1/1 assign dst_wd_o = src_q; Tests: T1 T2 T3  157 158 //////////////////////////// 159 // CDC handling 160 //////////////////////////// 161 162 logic dst_req_from_src; 163 logic dst_req; 164 165 166 // the software transaction is pulse synced across the domain. 167 // the prim_reg_cdc_arb module handles conflicts with ongoing hardware updates. 168 prim_pulse_sync u_src_to_dst_req ( 169 .clk_src_i, 170 .rst_src_ni, 171 .clk_dst_i, 172 .rst_dst_ni, 173 .src_pulse_i(src_req), 174 .dst_pulse_o(dst_req_from_src) 175 ); 176 177 prim_reg_cdc_arb #( 178 .DataWidth(DataWidth), 179 .ResetVal(ResetVal), 180 .DstWrReq(DstWrReq) 181 ) u_arb ( 182 .clk_src_i, 183 .rst_src_ni, 184 .clk_dst_i, 185 .rst_dst_ni, 186 .src_ack_o(src_ack), 187 .src_update_o(src_update), 188 .dst_req_i(dst_req_from_src), 189 .dst_req_o(dst_req), 190 .dst_update_i, 191 .dst_ds_i, 192 .dst_qs_i, 193 .dst_qs_o(dst_qs) 194 ); 195 196 197 // Each is valid only when destination request pulse is high; this is important in not propagating 198 // the internal assertion of 'dst_req' by the 'prim_pulse_sync' channel when just one domain is 199 // reset. 200 1/1 assign {dst_we_o, dst_re_o, dst_regwen_o} = txn_bits_q & {TxnWidth{dst_req}}; Tests: T1 T2 T3 

Cond Coverage for Instance : tb.dut.u_reg.u_wkup_ctrl_cdc
TotalCoveredPercent
Conditions111090.91
Logical111090.91
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10Unreachable
11Unreachable

Branch Coverage for Instance : tb.dut.u_reg.u_wkup_ctrl_cdc
Line No.TotalCoveredPercent
Branches 8 8 100.00
IF 71 4 4 100.00
IF 115 4 4 100.00


71 if (!rst_src_ni) begin -1- 72 src_busy_q <= '0; ==> 73 end else if (src_req) begin -2- 74 src_busy_q <= 1'b1; ==> 75 end else if (src_ack) begin -3- 76 src_busy_q <= 1'b0; ==> 77 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


115 if (!rst_src_ni) begin -1- 116 src_q <= ResetVal; ==> 117 txn_bits_q <= '0; 118 end else if (src_req) begin -2- 119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 src_q <= src_wd_i & BitMask; ==> 124 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; 125 end else if (src_busy_q && src_ack || src_update && !busy) begin -3- 126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 src_q <= dst_qs; ==> 135 txn_bits_q <= '0; 136 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


Assert Coverage for Instance : tb.dut.u_reg.u_wkup_ctrl_cdc
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 4 4 100.00 4 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 4 4 100.00 4 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
BusySrcReqChk_A 622911264 4448700 0 0
DstReqKnown_A 2404804 2314984 0 0
SrcAckBusyChk_A 622911264 4665 0 0
SrcBusyKnown_A 622911264 622684546 0 0


BusySrcReqChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 4448700 0 0
T1 11325 717 0 0
T2 22349 1712 0 0
T3 14739 960 0 0
T4 64450 1994 0 0
T5 39010 3103 0 0
T6 57759 2890 0 0
T7 287404 9300 0 0
T8 23380 1998 0 0
T9 0 730 0 0
T10 0 3341 0 0
T11 84540 0 0 0
T12 102683 0 0 0

DstReqKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2404804 2314984 0 0
T1 97 23 0 0
T2 90 25 0 0
T3 116 28 0 0
T4 329 246 0 0
T5 83 14 0 0
T6 118 22 0 0
T7 2394 1829 0 0
T8 92 21 0 0
T11 804 12 0 0
T12 1710 53 0 0

SrcAckBusyChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 4665 0 0
T1 11325 2 0 0
T2 22349 2 0 0
T3 14739 2 0 0
T4 64450 3 0 0
T5 39010 2 0 0
T6 57759 2 0 0
T7 287404 22 0 0
T8 23380 2 0 0
T9 0 2 0 0
T10 0 2 0 0
T11 84540 0 0 0
T12 102683 0 0 0

SrcBusyKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 622684546 0 0
T1 11325 11230 0 0
T2 22349 22268 0 0
T3 14739 14678 0 0
T4 64450 64391 0 0
T5 39010 38959 0 0
T6 57759 57707 0 0
T7 287404 286880 0 0
T8 23380 23288 0 0
T11 84540 83790 0 0
T12 102683 101011 0 0

Line Coverage for Instance : tb.dut.u_reg.u_wkup_thold_hi_cdc
Line No.TotalCoveredPercent
TOTAL2222100.00
CONT_ASSIGN6511100.00
ALWAYS7166100.00
CONT_ASSIGN8511100.00
CONT_ASSIGN10911100.00
ALWAYS11599100.00
CONT_ASSIGN15011100.00
CONT_ASSIGN15511100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN20011100.00

64 65 1/1 assign src_req = src_we_i | src_re_i; Tests: T1 T2 T3  66 67 // busy indication back-pressures upstream if the register is accessed 68 // again. The busy indication is also used as a "commit" indication for 69 // resolving software and hardware write conflicts 70 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 71 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  72 1/1 src_busy_q <= '0; Tests: T1 T2 T3  73 1/1 end else if (src_req) begin Tests: T1 T2 T3  74 1/1 src_busy_q <= 1'b1; Tests: T1 T2 T3  75 1/1 end else if (src_ack) begin Tests: T1 T2 T3  76 1/1 src_busy_q <= 1'b0; Tests: T1 T2 T3  77 end MISSING_ELSE 78 end 79 80 // A src_ack should only be sent if there was a src_req. 81 // src_busy_q asserts whenever there is a src_req. By association, 82 // whenever src_ack is seen, then src_busy must be high. 83 `ASSERT(SrcAckBusyChk_A, src_ack |-> src_busy_q, clk_src_i, !rst_src_ni) 84 85 1/1 assign src_busy_o = src_busy_q; Tests: T1 T2 T3  86 87 // src_q acts as both the write holding register and the software read back 88 // register. 89 // When software performs a write, the write data is captured in src_q for 90 // CDC purposes. When not performing a write, the src_q reflects the most recent 91 // hardware value. For registers with no hardware access, this is simply the 92 // the value programmed by software (or in the case R1C, W1C etc) the value after 93 // the operation. For registers with hardware access, this reflects a potentially 94 // delayed version of the real value, as the software facing updates lag real 95 // time updates. 96 // 97 // To resolve software and hardware conflicts, the process is as follows: 98 // When software issues a write, this module asserts "busy". While busy, 99 // src_q does not take on destination value updates. Since the 100 // logic has committed to updating based on software command, there is an irreversible 101 // window from which hardware writes are ignored. Once the busy window completes, 102 // the cdc portion then begins sampling once more. 103 // 104 // This is consistent with prim_subreg_arb where during software / hardware conflicts, 105 // software is always prioritized. The main difference is the conflict resolution window 106 // is now larger instead of just one destination clock cycle. 107 108 logic busy; 109 1/1 assign busy = src_busy_q & !src_ack; Tests: T1 T2 T3  110 111 // This is the current destination value 112 logic [DataWidth-1:0] dst_qs; 113 logic src_update; 114 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 115 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  116 1/1 src_q <= ResetVal; Tests: T1 T2 T3  117 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  118 1/1 end else if (src_req) begin Tests: T1 T2 T3  119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 1/1 src_q <= src_wd_i & BitMask; Tests: T1 T2 T3  124 1/1 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; Tests: T1 T2 T3  125 1/1 end else if (src_busy_q && src_ack || src_update && !busy) begin Tests: T1 T2 T3  126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 1/1 src_q <= dst_qs; Tests: T1 T2 T3  135 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  136 end MISSING_ELSE 137 end 138 139 // The current design (tlul_adapter_reg) does not spit out a request if the destination it chooses 140 // (decoded from address) is busy. So this creates a situation in the current design where 141 // src_req_i and busy can never be high at the same time. 142 // While the code above could be coded directly to be expressed as `src_req & !busy`, which makes 143 // the intent clearer, it ends up causing coverage holes from the tool's perspective since that 144 // condition cannot be met. 145 // Thus we add an assertion here to ensure the condition is always satisfied. 146 `ASSERT(BusySrcReqChk_A, busy |-> !src_req, clk_src_i, !rst_src_ni) 147 148 // reserved bits are not used 149 logic unused_wd; 150 1/1 assign unused_wd = ^src_wd_i; Tests: T1 T2 T3  151 152 // src_q is always updated in the clk_src domain. 153 // when performing an update to the destination domain, it is guaranteed 154 // to not change by protocol. 155 1/1 assign src_qs_o = src_q; Tests: T1 T2 T3  156 1/1 assign dst_wd_o = src_q; Tests: T1 T2 T3  157 158 //////////////////////////// 159 // CDC handling 160 //////////////////////////// 161 162 logic dst_req_from_src; 163 logic dst_req; 164 165 166 // the software transaction is pulse synced across the domain. 167 // the prim_reg_cdc_arb module handles conflicts with ongoing hardware updates. 168 prim_pulse_sync u_src_to_dst_req ( 169 .clk_src_i, 170 .rst_src_ni, 171 .clk_dst_i, 172 .rst_dst_ni, 173 .src_pulse_i(src_req), 174 .dst_pulse_o(dst_req_from_src) 175 ); 176 177 prim_reg_cdc_arb #( 178 .DataWidth(DataWidth), 179 .ResetVal(ResetVal), 180 .DstWrReq(DstWrReq) 181 ) u_arb ( 182 .clk_src_i, 183 .rst_src_ni, 184 .clk_dst_i, 185 .rst_dst_ni, 186 .src_ack_o(src_ack), 187 .src_update_o(src_update), 188 .dst_req_i(dst_req_from_src), 189 .dst_req_o(dst_req), 190 .dst_update_i, 191 .dst_ds_i, 192 .dst_qs_i, 193 .dst_qs_o(dst_qs) 194 ); 195 196 197 // Each is valid only when destination request pulse is high; this is important in not propagating 198 // the internal assertion of 'dst_req' by the 'prim_pulse_sync' channel when just one domain is 199 // reset. 200 1/1 assign {dst_we_o, dst_re_o, dst_regwen_o} = txn_bits_q & {TxnWidth{dst_req}}; Tests: T1 T2 T3 

Cond Coverage for Instance : tb.dut.u_reg.u_wkup_thold_hi_cdc
TotalCoveredPercent
Conditions111090.91
Logical111090.91
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10Unreachable
11Unreachable

Branch Coverage for Instance : tb.dut.u_reg.u_wkup_thold_hi_cdc
Line No.TotalCoveredPercent
Branches 8 8 100.00
IF 71 4 4 100.00
IF 115 4 4 100.00


71 if (!rst_src_ni) begin -1- 72 src_busy_q <= '0; ==> 73 end else if (src_req) begin -2- 74 src_busy_q <= 1'b1; ==> 75 end else if (src_ack) begin -3- 76 src_busy_q <= 1'b0; ==> 77 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


115 if (!rst_src_ni) begin -1- 116 src_q <= ResetVal; ==> 117 txn_bits_q <= '0; 118 end else if (src_req) begin -2- 119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 src_q <= src_wd_i & BitMask; ==> 124 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; 125 end else if (src_busy_q && src_ack || src_update && !busy) begin -3- 126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 src_q <= dst_qs; ==> 135 txn_bits_q <= '0; 136 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


Assert Coverage for Instance : tb.dut.u_reg.u_wkup_thold_hi_cdc
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 4 4 100.00 4 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 4 4 100.00 4 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
BusySrcReqChk_A 622911264 2441105 0 0
DstReqKnown_A 2404804 2314984 0 0
SrcAckBusyChk_A 622911264 2628 0 0
SrcBusyKnown_A 622911264 622684546 0 0


BusySrcReqChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 2441105 0 0
T1 11325 302 0 0
T2 22349 725 0 0
T3 14739 443 0 0
T4 64450 702 0 0
T5 39010 1779 0 0
T6 57759 1445 0 0
T7 287404 4123 0 0
T8 23380 991 0 0
T9 0 365 0 0
T10 0 1911 0 0
T11 84540 0 0 0
T12 102683 0 0 0

DstReqKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2404804 2314984 0 0
T1 97 23 0 0
T2 90 25 0 0
T3 116 28 0 0
T4 329 246 0 0
T5 83 14 0 0
T6 118 22 0 0
T7 2394 1829 0 0
T8 92 21 0 0
T11 804 12 0 0
T12 1710 53 0 0

SrcAckBusyChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 2628 0 0
T1 11325 1 0 0
T2 22349 1 0 0
T3 14739 1 0 0
T4 64450 1 0 0
T5 39010 1 0 0
T6 57759 1 0 0
T7 287404 10 0 0
T8 23380 1 0 0
T9 0 1 0 0
T10 0 1 0 0
T11 84540 0 0 0
T12 102683 0 0 0

SrcBusyKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 622684546 0 0
T1 11325 11230 0 0
T2 22349 22268 0 0
T3 14739 14678 0 0
T4 64450 64391 0 0
T5 39010 38959 0 0
T6 57759 57707 0 0
T7 287404 286880 0 0
T8 23380 23288 0 0
T11 84540 83790 0 0
T12 102683 101011 0 0

Line Coverage for Instance : tb.dut.u_reg.u_wkup_thold_lo_cdc
Line No.TotalCoveredPercent
TOTAL2222100.00
CONT_ASSIGN6511100.00
ALWAYS7166100.00
CONT_ASSIGN8511100.00
CONT_ASSIGN10911100.00
ALWAYS11599100.00
CONT_ASSIGN15011100.00
CONT_ASSIGN15511100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN20011100.00

64 65 1/1 assign src_req = src_we_i | src_re_i; Tests: T1 T2 T3  66 67 // busy indication back-pressures upstream if the register is accessed 68 // again. The busy indication is also used as a "commit" indication for 69 // resolving software and hardware write conflicts 70 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 71 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  72 1/1 src_busy_q <= '0; Tests: T1 T2 T3  73 1/1 end else if (src_req) begin Tests: T1 T2 T3  74 1/1 src_busy_q <= 1'b1; Tests: T1 T2 T3  75 1/1 end else if (src_ack) begin Tests: T1 T2 T3  76 1/1 src_busy_q <= 1'b0; Tests: T1 T2 T3  77 end MISSING_ELSE 78 end 79 80 // A src_ack should only be sent if there was a src_req. 81 // src_busy_q asserts whenever there is a src_req. By association, 82 // whenever src_ack is seen, then src_busy must be high. 83 `ASSERT(SrcAckBusyChk_A, src_ack |-> src_busy_q, clk_src_i, !rst_src_ni) 84 85 1/1 assign src_busy_o = src_busy_q; Tests: T1 T2 T3  86 87 // src_q acts as both the write holding register and the software read back 88 // register. 89 // When software performs a write, the write data is captured in src_q for 90 // CDC purposes. When not performing a write, the src_q reflects the most recent 91 // hardware value. For registers with no hardware access, this is simply the 92 // the value programmed by software (or in the case R1C, W1C etc) the value after 93 // the operation. For registers with hardware access, this reflects a potentially 94 // delayed version of the real value, as the software facing updates lag real 95 // time updates. 96 // 97 // To resolve software and hardware conflicts, the process is as follows: 98 // When software issues a write, this module asserts "busy". While busy, 99 // src_q does not take on destination value updates. Since the 100 // logic has committed to updating based on software command, there is an irreversible 101 // window from which hardware writes are ignored. Once the busy window completes, 102 // the cdc portion then begins sampling once more. 103 // 104 // This is consistent with prim_subreg_arb where during software / hardware conflicts, 105 // software is always prioritized. The main difference is the conflict resolution window 106 // is now larger instead of just one destination clock cycle. 107 108 logic busy; 109 1/1 assign busy = src_busy_q & !src_ack; Tests: T1 T2 T3  110 111 // This is the current destination value 112 logic [DataWidth-1:0] dst_qs; 113 logic src_update; 114 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 115 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  116 1/1 src_q <= ResetVal; Tests: T1 T2 T3  117 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  118 1/1 end else if (src_req) begin Tests: T1 T2 T3  119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 1/1 src_q <= src_wd_i & BitMask; Tests: T1 T2 T3  124 1/1 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; Tests: T1 T2 T3  125 1/1 end else if (src_busy_q && src_ack || src_update && !busy) begin Tests: T1 T2 T3  126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 1/1 src_q <= dst_qs; Tests: T1 T2 T3  135 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  136 end MISSING_ELSE 137 end 138 139 // The current design (tlul_adapter_reg) does not spit out a request if the destination it chooses 140 // (decoded from address) is busy. So this creates a situation in the current design where 141 // src_req_i and busy can never be high at the same time. 142 // While the code above could be coded directly to be expressed as `src_req & !busy`, which makes 143 // the intent clearer, it ends up causing coverage holes from the tool's perspective since that 144 // condition cannot be met. 145 // Thus we add an assertion here to ensure the condition is always satisfied. 146 `ASSERT(BusySrcReqChk_A, busy |-> !src_req, clk_src_i, !rst_src_ni) 147 148 // reserved bits are not used 149 logic unused_wd; 150 1/1 assign unused_wd = ^src_wd_i; Tests: T1 T2 T3  151 152 // src_q is always updated in the clk_src domain. 153 // when performing an update to the destination domain, it is guaranteed 154 // to not change by protocol. 155 1/1 assign src_qs_o = src_q; Tests: T1 T2 T3  156 1/1 assign dst_wd_o = src_q; Tests: T1 T2 T3  157 158 //////////////////////////// 159 // CDC handling 160 //////////////////////////// 161 162 logic dst_req_from_src; 163 logic dst_req; 164 165 166 // the software transaction is pulse synced across the domain. 167 // the prim_reg_cdc_arb module handles conflicts with ongoing hardware updates. 168 prim_pulse_sync u_src_to_dst_req ( 169 .clk_src_i, 170 .rst_src_ni, 171 .clk_dst_i, 172 .rst_dst_ni, 173 .src_pulse_i(src_req), 174 .dst_pulse_o(dst_req_from_src) 175 ); 176 177 prim_reg_cdc_arb #( 178 .DataWidth(DataWidth), 179 .ResetVal(ResetVal), 180 .DstWrReq(DstWrReq) 181 ) u_arb ( 182 .clk_src_i, 183 .rst_src_ni, 184 .clk_dst_i, 185 .rst_dst_ni, 186 .src_ack_o(src_ack), 187 .src_update_o(src_update), 188 .dst_req_i(dst_req_from_src), 189 .dst_req_o(dst_req), 190 .dst_update_i, 191 .dst_ds_i, 192 .dst_qs_i, 193 .dst_qs_o(dst_qs) 194 ); 195 196 197 // Each is valid only when destination request pulse is high; this is important in not propagating 198 // the internal assertion of 'dst_req' by the 'prim_pulse_sync' channel when just one domain is 199 // reset. 200 1/1 assign {dst_we_o, dst_re_o, dst_regwen_o} = txn_bits_q & {TxnWidth{dst_req}}; Tests: T1 T2 T3 

Cond Coverage for Instance : tb.dut.u_reg.u_wkup_thold_lo_cdc
TotalCoveredPercent
Conditions111090.91
Logical111090.91
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10Unreachable
11Unreachable

Branch Coverage for Instance : tb.dut.u_reg.u_wkup_thold_lo_cdc
Line No.TotalCoveredPercent
Branches 8 8 100.00
IF 71 4 4 100.00
IF 115 4 4 100.00


71 if (!rst_src_ni) begin -1- 72 src_busy_q <= '0; ==> 73 end else if (src_req) begin -2- 74 src_busy_q <= 1'b1; ==> 75 end else if (src_ack) begin -3- 76 src_busy_q <= 1'b0; ==> 77 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


115 if (!rst_src_ni) begin -1- 116 src_q <= ResetVal; ==> 117 txn_bits_q <= '0; 118 end else if (src_req) begin -2- 119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 src_q <= src_wd_i & BitMask; ==> 124 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; 125 end else if (src_busy_q && src_ack || src_update && !busy) begin -3- 126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 src_q <= dst_qs; ==> 135 txn_bits_q <= '0; 136 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


Assert Coverage for Instance : tb.dut.u_reg.u_wkup_thold_lo_cdc
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 4 4 100.00 4 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 4 4 100.00 4 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
BusySrcReqChk_A 622911264 2467350 0 0
DstReqKnown_A 2404804 2314984 0 0
SrcAckBusyChk_A 622911264 2669 0 0
SrcBusyKnown_A 622911264 622684546 0 0


BusySrcReqChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 2467350 0 0
T1 11325 308 0 0
T2 22349 727 0 0
T3 14739 450 0 0
T4 64450 711 0 0
T5 39010 1790 0 0
T6 57759 1447 0 0
T7 287404 4143 0 0
T8 23380 993 0 0
T9 0 367 0 0
T10 0 1913 0 0
T11 84540 0 0 0
T12 102683 0 0 0

DstReqKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2404804 2314984 0 0
T1 97 23 0 0
T2 90 25 0 0
T3 116 28 0 0
T4 329 246 0 0
T5 83 14 0 0
T6 118 22 0 0
T7 2394 1829 0 0
T8 92 21 0 0
T11 804 12 0 0
T12 1710 53 0 0

SrcAckBusyChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 2669 0 0
T1 11325 1 0 0
T2 22349 1 0 0
T3 14739 1 0 0
T4 64450 1 0 0
T5 39010 1 0 0
T6 57759 1 0 0
T7 287404 10 0 0
T8 23380 1 0 0
T9 0 1 0 0
T10 0 1 0 0
T11 84540 0 0 0
T12 102683 0 0 0

SrcBusyKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 622684546 0 0
T1 11325 11230 0 0
T2 22349 22268 0 0
T3 14739 14678 0 0
T4 64450 64391 0 0
T5 39010 38959 0 0
T6 57759 57707 0 0
T7 287404 286880 0 0
T8 23380 23288 0 0
T11 84540 83790 0 0
T12 102683 101011 0 0

Line Coverage for Instance : tb.dut.u_reg.u_wdog_ctrl_cdc
Line No.TotalCoveredPercent
TOTAL2222100.00
CONT_ASSIGN6511100.00
ALWAYS7166100.00
CONT_ASSIGN8511100.00
CONT_ASSIGN10911100.00
ALWAYS11599100.00
CONT_ASSIGN15011100.00
CONT_ASSIGN15511100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN20011100.00

64 65 1/1 assign src_req = src_we_i | src_re_i; Tests: T1 T2 T3  66 67 // busy indication back-pressures upstream if the register is accessed 68 // again. The busy indication is also used as a "commit" indication for 69 // resolving software and hardware write conflicts 70 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 71 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  72 1/1 src_busy_q <= '0; Tests: T1 T2 T3  73 1/1 end else if (src_req) begin Tests: T1 T2 T3  74 1/1 src_busy_q <= 1'b1; Tests: T1 T2 T3  75 1/1 end else if (src_ack) begin Tests: T1 T2 T3  76 1/1 src_busy_q <= 1'b0; Tests: T1 T2 T3  77 end MISSING_ELSE 78 end 79 80 // A src_ack should only be sent if there was a src_req. 81 // src_busy_q asserts whenever there is a src_req. By association, 82 // whenever src_ack is seen, then src_busy must be high. 83 `ASSERT(SrcAckBusyChk_A, src_ack |-> src_busy_q, clk_src_i, !rst_src_ni) 84 85 1/1 assign src_busy_o = src_busy_q; Tests: T1 T2 T3  86 87 // src_q acts as both the write holding register and the software read back 88 // register. 89 // When software performs a write, the write data is captured in src_q for 90 // CDC purposes. When not performing a write, the src_q reflects the most recent 91 // hardware value. For registers with no hardware access, this is simply the 92 // the value programmed by software (or in the case R1C, W1C etc) the value after 93 // the operation. For registers with hardware access, this reflects a potentially 94 // delayed version of the real value, as the software facing updates lag real 95 // time updates. 96 // 97 // To resolve software and hardware conflicts, the process is as follows: 98 // When software issues a write, this module asserts "busy". While busy, 99 // src_q does not take on destination value updates. Since the 100 // logic has committed to updating based on software command, there is an irreversible 101 // window from which hardware writes are ignored. Once the busy window completes, 102 // the cdc portion then begins sampling once more. 103 // 104 // This is consistent with prim_subreg_arb where during software / hardware conflicts, 105 // software is always prioritized. The main difference is the conflict resolution window 106 // is now larger instead of just one destination clock cycle. 107 108 logic busy; 109 1/1 assign busy = src_busy_q & !src_ack; Tests: T1 T2 T3  110 111 // This is the current destination value 112 logic [DataWidth-1:0] dst_qs; 113 logic src_update; 114 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 115 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  116 1/1 src_q <= ResetVal; Tests: T1 T2 T3  117 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  118 1/1 end else if (src_req) begin Tests: T1 T2 T3  119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 1/1 src_q <= src_wd_i & BitMask; Tests: T1 T2 T3  124 1/1 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; Tests: T1 T2 T3  125 1/1 end else if (src_busy_q && src_ack || src_update && !busy) begin Tests: T1 T2 T3  126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 1/1 src_q <= dst_qs; Tests: T1 T2 T3  135 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  136 end MISSING_ELSE 137 end 138 139 // The current design (tlul_adapter_reg) does not spit out a request if the destination it chooses 140 // (decoded from address) is busy. So this creates a situation in the current design where 141 // src_req_i and busy can never be high at the same time. 142 // While the code above could be coded directly to be expressed as `src_req & !busy`, which makes 143 // the intent clearer, it ends up causing coverage holes from the tool's perspective since that 144 // condition cannot be met. 145 // Thus we add an assertion here to ensure the condition is always satisfied. 146 `ASSERT(BusySrcReqChk_A, busy |-> !src_req, clk_src_i, !rst_src_ni) 147 148 // reserved bits are not used 149 logic unused_wd; 150 1/1 assign unused_wd = ^src_wd_i; Tests: T1 T2 T3  151 152 // src_q is always updated in the clk_src domain. 153 // when performing an update to the destination domain, it is guaranteed 154 // to not change by protocol. 155 1/1 assign src_qs_o = src_q; Tests: T1 T2 T3  156 1/1 assign dst_wd_o = src_q; Tests: T1 T2 T3  157 158 //////////////////////////// 159 // CDC handling 160 //////////////////////////// 161 162 logic dst_req_from_src; 163 logic dst_req; 164 165 166 // the software transaction is pulse synced across the domain. 167 // the prim_reg_cdc_arb module handles conflicts with ongoing hardware updates. 168 prim_pulse_sync u_src_to_dst_req ( 169 .clk_src_i, 170 .rst_src_ni, 171 .clk_dst_i, 172 .rst_dst_ni, 173 .src_pulse_i(src_req), 174 .dst_pulse_o(dst_req_from_src) 175 ); 176 177 prim_reg_cdc_arb #( 178 .DataWidth(DataWidth), 179 .ResetVal(ResetVal), 180 .DstWrReq(DstWrReq) 181 ) u_arb ( 182 .clk_src_i, 183 .rst_src_ni, 184 .clk_dst_i, 185 .rst_dst_ni, 186 .src_ack_o(src_ack), 187 .src_update_o(src_update), 188 .dst_req_i(dst_req_from_src), 189 .dst_req_o(dst_req), 190 .dst_update_i, 191 .dst_ds_i, 192 .dst_qs_i, 193 .dst_qs_o(dst_qs) 194 ); 195 196 197 // Each is valid only when destination request pulse is high; this is important in not propagating 198 // the internal assertion of 'dst_req' by the 'prim_pulse_sync' channel when just one domain is 199 // reset. 200 1/1 assign {dst_we_o, dst_re_o, dst_regwen_o} = txn_bits_q & {TxnWidth{dst_req}}; Tests: T1 T2 T3 

Cond Coverage for Instance : tb.dut.u_reg.u_wdog_ctrl_cdc
TotalCoveredPercent
Conditions111090.91
Logical111090.91
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10Unreachable
11Unreachable

Branch Coverage for Instance : tb.dut.u_reg.u_wdog_ctrl_cdc
Line No.TotalCoveredPercent
Branches 8 8 100.00
IF 71 4 4 100.00
IF 115 4 4 100.00


71 if (!rst_src_ni) begin -1- 72 src_busy_q <= '0; ==> 73 end else if (src_req) begin -2- 74 src_busy_q <= 1'b1; ==> 75 end else if (src_ack) begin -3- 76 src_busy_q <= 1'b0; ==> 77 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


115 if (!rst_src_ni) begin -1- 116 src_q <= ResetVal; ==> 117 txn_bits_q <= '0; 118 end else if (src_req) begin -2- 119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 src_q <= src_wd_i & BitMask; ==> 124 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; 125 end else if (src_busy_q && src_ack || src_update && !busy) begin -3- 126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 src_q <= dst_qs; ==> 135 txn_bits_q <= '0; 136 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


Assert Coverage for Instance : tb.dut.u_reg.u_wdog_ctrl_cdc
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 4 4 100.00 4 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 4 4 100.00 4 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
BusySrcReqChk_A 622911264 3486314 0 0
DstReqKnown_A 2404804 2314984 0 0
SrcAckBusyChk_A 622911264 3635 0 0
SrcBusyKnown_A 622911264 622684546 0 0


BusySrcReqChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 3486314 0 0
T1 11325 317 0 0
T2 22349 1712 0 0
T3 14739 958 0 0
T4 64450 1521 0 0
T5 39010 3082 0 0
T6 57759 2886 0 0
T7 287404 8086 0 0
T8 23380 1998 0 0
T9 0 371 0 0
T10 0 1917 0 0
T11 84540 0 0 0
T12 102683 0 0 0

DstReqKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2404804 2314984 0 0
T1 97 23 0 0
T2 90 25 0 0
T3 116 28 0 0
T4 329 246 0 0
T5 83 14 0 0
T6 118 22 0 0
T7 2394 1829 0 0
T8 92 21 0 0
T11 804 12 0 0
T12 1710 53 0 0

SrcAckBusyChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 3635 0 0
T1 11325 1 0 0
T2 22349 2 0 0
T3 14739 2 0 0
T4 64450 2 0 0
T5 39010 2 0 0
T6 57759 2 0 0
T7 287404 19 0 0
T8 23380 2 0 0
T9 0 1 0 0
T10 0 1 0 0
T11 84540 0 0 0
T12 102683 0 0 0

SrcBusyKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 622684546 0 0
T1 11325 11230 0 0
T2 22349 22268 0 0
T3 14739 14678 0 0
T4 64450 64391 0 0
T5 39010 38959 0 0
T6 57759 57707 0 0
T7 287404 286880 0 0
T8 23380 23288 0 0
T11 84540 83790 0 0
T12 102683 101011 0 0

Line Coverage for Instance : tb.dut.u_reg.u_wdog_bark_thold_cdc
Line No.TotalCoveredPercent
TOTAL2222100.00
CONT_ASSIGN6511100.00
ALWAYS7166100.00
CONT_ASSIGN8511100.00
CONT_ASSIGN10911100.00
ALWAYS11599100.00
CONT_ASSIGN15011100.00
CONT_ASSIGN15511100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN20011100.00

64 65 1/1 assign src_req = src_we_i | src_re_i; Tests: T1 T2 T3  66 67 // busy indication back-pressures upstream if the register is accessed 68 // again. The busy indication is also used as a "commit" indication for 69 // resolving software and hardware write conflicts 70 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 71 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  72 1/1 src_busy_q <= '0; Tests: T1 T2 T3  73 1/1 end else if (src_req) begin Tests: T1 T2 T3  74 1/1 src_busy_q <= 1'b1; Tests: T1 T2 T3  75 1/1 end else if (src_ack) begin Tests: T1 T2 T3  76 1/1 src_busy_q <= 1'b0; Tests: T1 T2 T3  77 end MISSING_ELSE 78 end 79 80 // A src_ack should only be sent if there was a src_req. 81 // src_busy_q asserts whenever there is a src_req. By association, 82 // whenever src_ack is seen, then src_busy must be high. 83 `ASSERT(SrcAckBusyChk_A, src_ack |-> src_busy_q, clk_src_i, !rst_src_ni) 84 85 1/1 assign src_busy_o = src_busy_q; Tests: T1 T2 T3  86 87 // src_q acts as both the write holding register and the software read back 88 // register. 89 // When software performs a write, the write data is captured in src_q for 90 // CDC purposes. When not performing a write, the src_q reflects the most recent 91 // hardware value. For registers with no hardware access, this is simply the 92 // the value programmed by software (or in the case R1C, W1C etc) the value after 93 // the operation. For registers with hardware access, this reflects a potentially 94 // delayed version of the real value, as the software facing updates lag real 95 // time updates. 96 // 97 // To resolve software and hardware conflicts, the process is as follows: 98 // When software issues a write, this module asserts "busy". While busy, 99 // src_q does not take on destination value updates. Since the 100 // logic has committed to updating based on software command, there is an irreversible 101 // window from which hardware writes are ignored. Once the busy window completes, 102 // the cdc portion then begins sampling once more. 103 // 104 // This is consistent with prim_subreg_arb where during software / hardware conflicts, 105 // software is always prioritized. The main difference is the conflict resolution window 106 // is now larger instead of just one destination clock cycle. 107 108 logic busy; 109 1/1 assign busy = src_busy_q & !src_ack; Tests: T1 T2 T3  110 111 // This is the current destination value 112 logic [DataWidth-1:0] dst_qs; 113 logic src_update; 114 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 115 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  116 1/1 src_q <= ResetVal; Tests: T1 T2 T3  117 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  118 1/1 end else if (src_req) begin Tests: T1 T2 T3  119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 1/1 src_q <= src_wd_i & BitMask; Tests: T1 T2 T3  124 1/1 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; Tests: T1 T2 T3  125 1/1 end else if (src_busy_q && src_ack || src_update && !busy) begin Tests: T1 T2 T3  126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 1/1 src_q <= dst_qs; Tests: T1 T2 T3  135 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  136 end MISSING_ELSE 137 end 138 139 // The current design (tlul_adapter_reg) does not spit out a request if the destination it chooses 140 // (decoded from address) is busy. So this creates a situation in the current design where 141 // src_req_i and busy can never be high at the same time. 142 // While the code above could be coded directly to be expressed as `src_req & !busy`, which makes 143 // the intent clearer, it ends up causing coverage holes from the tool's perspective since that 144 // condition cannot be met. 145 // Thus we add an assertion here to ensure the condition is always satisfied. 146 `ASSERT(BusySrcReqChk_A, busy |-> !src_req, clk_src_i, !rst_src_ni) 147 148 // reserved bits are not used 149 logic unused_wd; 150 1/1 assign unused_wd = ^src_wd_i; Tests: T1 T2 T3  151 152 // src_q is always updated in the clk_src domain. 153 // when performing an update to the destination domain, it is guaranteed 154 // to not change by protocol. 155 1/1 assign src_qs_o = src_q; Tests: T1 T2 T3  156 1/1 assign dst_wd_o = src_q; Tests: T1 T2 T3  157 158 //////////////////////////// 159 // CDC handling 160 //////////////////////////// 161 162 logic dst_req_from_src; 163 logic dst_req; 164 165 166 // the software transaction is pulse synced across the domain. 167 // the prim_reg_cdc_arb module handles conflicts with ongoing hardware updates. 168 prim_pulse_sync u_src_to_dst_req ( 169 .clk_src_i, 170 .rst_src_ni, 171 .clk_dst_i, 172 .rst_dst_ni, 173 .src_pulse_i(src_req), 174 .dst_pulse_o(dst_req_from_src) 175 ); 176 177 prim_reg_cdc_arb #( 178 .DataWidth(DataWidth), 179 .ResetVal(ResetVal), 180 .DstWrReq(DstWrReq) 181 ) u_arb ( 182 .clk_src_i, 183 .rst_src_ni, 184 .clk_dst_i, 185 .rst_dst_ni, 186 .src_ack_o(src_ack), 187 .src_update_o(src_update), 188 .dst_req_i(dst_req_from_src), 189 .dst_req_o(dst_req), 190 .dst_update_i, 191 .dst_ds_i, 192 .dst_qs_i, 193 .dst_qs_o(dst_qs) 194 ); 195 196 197 // Each is valid only when destination request pulse is high; this is important in not propagating 198 // the internal assertion of 'dst_req' by the 'prim_pulse_sync' channel when just one domain is 199 // reset. 200 1/1 assign {dst_we_o, dst_re_o, dst_regwen_o} = txn_bits_q & {TxnWidth{dst_req}}; Tests: T1 T2 T3 

Cond Coverage for Instance : tb.dut.u_reg.u_wdog_bark_thold_cdc
TotalCoveredPercent
Conditions111090.91
Logical111090.91
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10Unreachable
11Unreachable

Branch Coverage for Instance : tb.dut.u_reg.u_wdog_bark_thold_cdc
Line No.TotalCoveredPercent
Branches 8 8 100.00
IF 71 4 4 100.00
IF 115 4 4 100.00


71 if (!rst_src_ni) begin -1- 72 src_busy_q <= '0; ==> 73 end else if (src_req) begin -2- 74 src_busy_q <= 1'b1; ==> 75 end else if (src_ack) begin -3- 76 src_busy_q <= 1'b0; ==> 77 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


115 if (!rst_src_ni) begin -1- 116 src_q <= ResetVal; ==> 117 txn_bits_q <= '0; 118 end else if (src_req) begin -2- 119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 src_q <= src_wd_i & BitMask; ==> 124 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; 125 end else if (src_busy_q && src_ack || src_update && !busy) begin -3- 126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 src_q <= dst_qs; ==> 135 txn_bits_q <= '0; 136 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


Assert Coverage for Instance : tb.dut.u_reg.u_wdog_bark_thold_cdc
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 4 4 100.00 4 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 4 4 100.00 4 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
BusySrcReqChk_A 622911264 2482992 0 0
DstReqKnown_A 2404804 2314984 0 0
SrcAckBusyChk_A 622911264 2696 0 0
SrcBusyKnown_A 622911264 622684546 0 0


BusySrcReqChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 2482992 0 0
T1 11325 300 0 0
T2 22349 723 0 0
T3 14739 441 0 0
T4 64450 687 0 0
T5 39010 1772 0 0
T6 57759 1443 0 0
T7 287404 4103 0 0
T8 23380 989 0 0
T9 0 363 0 0
T10 0 1909 0 0
T11 84540 0 0 0
T12 102683 0 0 0

DstReqKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2404804 2314984 0 0
T1 97 23 0 0
T2 90 25 0 0
T3 116 28 0 0
T4 329 246 0 0
T5 83 14 0 0
T6 118 22 0 0
T7 2394 1829 0 0
T8 92 21 0 0
T11 804 12 0 0
T12 1710 53 0 0

SrcAckBusyChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 2696 0 0
T1 11325 1 0 0
T2 22349 1 0 0
T3 14739 1 0 0
T4 64450 1 0 0
T5 39010 1 0 0
T6 57759 1 0 0
T7 287404 10 0 0
T8 23380 1 0 0
T9 0 1 0 0
T10 0 1 0 0
T11 84540 0 0 0
T12 102683 0 0 0

SrcBusyKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 622684546 0 0
T1 11325 11230 0 0
T2 22349 22268 0 0
T3 14739 14678 0 0
T4 64450 64391 0 0
T5 39010 38959 0 0
T6 57759 57707 0 0
T7 287404 286880 0 0
T8 23380 23288 0 0
T11 84540 83790 0 0
T12 102683 101011 0 0

Line Coverage for Instance : tb.dut.u_reg.u_wdog_bite_thold_cdc
Line No.TotalCoveredPercent
TOTAL2222100.00
CONT_ASSIGN6511100.00
ALWAYS7166100.00
CONT_ASSIGN8511100.00
CONT_ASSIGN10911100.00
ALWAYS11599100.00
CONT_ASSIGN15011100.00
CONT_ASSIGN15511100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN20011100.00

64 65 1/1 assign src_req = src_we_i | src_re_i; Tests: T1 T2 T3  66 67 // busy indication back-pressures upstream if the register is accessed 68 // again. The busy indication is also used as a "commit" indication for 69 // resolving software and hardware write conflicts 70 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 71 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  72 1/1 src_busy_q <= '0; Tests: T1 T2 T3  73 1/1 end else if (src_req) begin Tests: T1 T2 T3  74 1/1 src_busy_q <= 1'b1; Tests: T1 T2 T3  75 1/1 end else if (src_ack) begin Tests: T1 T2 T3  76 1/1 src_busy_q <= 1'b0; Tests: T1 T2 T3  77 end MISSING_ELSE 78 end 79 80 // A src_ack should only be sent if there was a src_req. 81 // src_busy_q asserts whenever there is a src_req. By association, 82 // whenever src_ack is seen, then src_busy must be high. 83 `ASSERT(SrcAckBusyChk_A, src_ack |-> src_busy_q, clk_src_i, !rst_src_ni) 84 85 1/1 assign src_busy_o = src_busy_q; Tests: T1 T2 T3  86 87 // src_q acts as both the write holding register and the software read back 88 // register. 89 // When software performs a write, the write data is captured in src_q for 90 // CDC purposes. When not performing a write, the src_q reflects the most recent 91 // hardware value. For registers with no hardware access, this is simply the 92 // the value programmed by software (or in the case R1C, W1C etc) the value after 93 // the operation. For registers with hardware access, this reflects a potentially 94 // delayed version of the real value, as the software facing updates lag real 95 // time updates. 96 // 97 // To resolve software and hardware conflicts, the process is as follows: 98 // When software issues a write, this module asserts "busy". While busy, 99 // src_q does not take on destination value updates. Since the 100 // logic has committed to updating based on software command, there is an irreversible 101 // window from which hardware writes are ignored. Once the busy window completes, 102 // the cdc portion then begins sampling once more. 103 // 104 // This is consistent with prim_subreg_arb where during software / hardware conflicts, 105 // software is always prioritized. The main difference is the conflict resolution window 106 // is now larger instead of just one destination clock cycle. 107 108 logic busy; 109 1/1 assign busy = src_busy_q & !src_ack; Tests: T1 T2 T3  110 111 // This is the current destination value 112 logic [DataWidth-1:0] dst_qs; 113 logic src_update; 114 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 115 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  116 1/1 src_q <= ResetVal; Tests: T1 T2 T3  117 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  118 1/1 end else if (src_req) begin Tests: T1 T2 T3  119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 1/1 src_q <= src_wd_i & BitMask; Tests: T1 T2 T3  124 1/1 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; Tests: T1 T2 T3  125 1/1 end else if (src_busy_q && src_ack || src_update && !busy) begin Tests: T1 T2 T3  126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 1/1 src_q <= dst_qs; Tests: T1 T2 T3  135 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  136 end MISSING_ELSE 137 end 138 139 // The current design (tlul_adapter_reg) does not spit out a request if the destination it chooses 140 // (decoded from address) is busy. So this creates a situation in the current design where 141 // src_req_i and busy can never be high at the same time. 142 // While the code above could be coded directly to be expressed as `src_req & !busy`, which makes 143 // the intent clearer, it ends up causing coverage holes from the tool's perspective since that 144 // condition cannot be met. 145 // Thus we add an assertion here to ensure the condition is always satisfied. 146 `ASSERT(BusySrcReqChk_A, busy |-> !src_req, clk_src_i, !rst_src_ni) 147 148 // reserved bits are not used 149 logic unused_wd; 150 1/1 assign unused_wd = ^src_wd_i; Tests: T1 T2 T3  151 152 // src_q is always updated in the clk_src domain. 153 // when performing an update to the destination domain, it is guaranteed 154 // to not change by protocol. 155 1/1 assign src_qs_o = src_q; Tests: T1 T2 T3  156 1/1 assign dst_wd_o = src_q; Tests: T1 T2 T3  157 158 //////////////////////////// 159 // CDC handling 160 //////////////////////////// 161 162 logic dst_req_from_src; 163 logic dst_req; 164 165 166 // the software transaction is pulse synced across the domain. 167 // the prim_reg_cdc_arb module handles conflicts with ongoing hardware updates. 168 prim_pulse_sync u_src_to_dst_req ( 169 .clk_src_i, 170 .rst_src_ni, 171 .clk_dst_i, 172 .rst_dst_ni, 173 .src_pulse_i(src_req), 174 .dst_pulse_o(dst_req_from_src) 175 ); 176 177 prim_reg_cdc_arb #( 178 .DataWidth(DataWidth), 179 .ResetVal(ResetVal), 180 .DstWrReq(DstWrReq) 181 ) u_arb ( 182 .clk_src_i, 183 .rst_src_ni, 184 .clk_dst_i, 185 .rst_dst_ni, 186 .src_ack_o(src_ack), 187 .src_update_o(src_update), 188 .dst_req_i(dst_req_from_src), 189 .dst_req_o(dst_req), 190 .dst_update_i, 191 .dst_ds_i, 192 .dst_qs_i, 193 .dst_qs_o(dst_qs) 194 ); 195 196 197 // Each is valid only when destination request pulse is high; this is important in not propagating 198 // the internal assertion of 'dst_req' by the 'prim_pulse_sync' channel when just one domain is 199 // reset. 200 1/1 assign {dst_we_o, dst_re_o, dst_regwen_o} = txn_bits_q & {TxnWidth{dst_req}}; Tests: T1 T2 T3 

Cond Coverage for Instance : tb.dut.u_reg.u_wdog_bite_thold_cdc
TotalCoveredPercent
Conditions111090.91
Logical111090.91
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10Unreachable
11Unreachable

Branch Coverage for Instance : tb.dut.u_reg.u_wdog_bite_thold_cdc
Line No.TotalCoveredPercent
Branches 8 8 100.00
IF 71 4 4 100.00
IF 115 4 4 100.00


71 if (!rst_src_ni) begin -1- 72 src_busy_q <= '0; ==> 73 end else if (src_req) begin -2- 74 src_busy_q <= 1'b1; ==> 75 end else if (src_ack) begin -3- 76 src_busy_q <= 1'b0; ==> 77 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


115 if (!rst_src_ni) begin -1- 116 src_q <= ResetVal; ==> 117 txn_bits_q <= '0; 118 end else if (src_req) begin -2- 119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 src_q <= src_wd_i & BitMask; ==> 124 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; 125 end else if (src_busy_q && src_ack || src_update && !busy) begin -3- 126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 src_q <= dst_qs; ==> 135 txn_bits_q <= '0; 136 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


Assert Coverage for Instance : tb.dut.u_reg.u_wdog_bite_thold_cdc
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 4 4 100.00 4 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 4 4 100.00 4 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
BusySrcReqChk_A 622911264 2420840 0 0
DstReqKnown_A 2404804 2314984 0 0
SrcAckBusyChk_A 622911264 2636 0 0
SrcBusyKnown_A 622911264 622684546 0 0


BusySrcReqChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 2420840 0 0
T1 11325 292 0 0
T2 22349 721 0 0
T3 14739 428 0 0
T4 64450 674 0 0
T5 39010 1760 0 0
T6 57759 1441 0 0
T7 287404 4083 0 0
T8 23380 987 0 0
T9 0 361 0 0
T10 0 1907 0 0
T11 84540 0 0 0
T12 102683 0 0 0

DstReqKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2404804 2314984 0 0
T1 97 23 0 0
T2 90 25 0 0
T3 116 28 0 0
T4 329 246 0 0
T5 83 14 0 0
T6 118 22 0 0
T7 2394 1829 0 0
T8 92 21 0 0
T11 804 12 0 0
T12 1710 53 0 0

SrcAckBusyChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 2636 0 0
T1 11325 1 0 0
T2 22349 1 0 0
T3 14739 1 0 0
T4 64450 1 0 0
T5 39010 1 0 0
T6 57759 1 0 0
T7 287404 10 0 0
T8 23380 1 0 0
T9 0 1 0 0
T10 0 1 0 0
T11 84540 0 0 0
T12 102683 0 0 0

SrcBusyKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 622684546 0 0
T1 11325 11230 0 0
T2 22349 22268 0 0
T3 14739 14678 0 0
T4 64450 64391 0 0
T5 39010 38959 0 0
T6 57759 57707 0 0
T7 287404 286880 0 0
T8 23380 23288 0 0
T11 84540 83790 0 0
T12 102683 101011 0 0

Line Coverage for Instance : tb.dut.u_reg.u_wkup_count_lo_cdc
Line No.TotalCoveredPercent
TOTAL2222100.00
CONT_ASSIGN6511100.00
ALWAYS7166100.00
CONT_ASSIGN8511100.00
CONT_ASSIGN10911100.00
ALWAYS11599100.00
CONT_ASSIGN15011100.00
CONT_ASSIGN15511100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN20011100.00

64 65 1/1 assign src_req = src_we_i | src_re_i; Tests: T1 T2 T3  66 67 // busy indication back-pressures upstream if the register is accessed 68 // again. The busy indication is also used as a "commit" indication for 69 // resolving software and hardware write conflicts 70 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 71 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  72 1/1 src_busy_q <= '0; Tests: T1 T2 T3  73 1/1 end else if (src_req) begin Tests: T1 T2 T3  74 1/1 src_busy_q <= 1'b1; Tests: T1 T2 T3  75 1/1 end else if (src_ack) begin Tests: T1 T2 T3  76 1/1 src_busy_q <= 1'b0; Tests: T1 T2 T3  77 end MISSING_ELSE 78 end 79 80 // A src_ack should only be sent if there was a src_req. 81 // src_busy_q asserts whenever there is a src_req. By association, 82 // whenever src_ack is seen, then src_busy must be high. 83 `ASSERT(SrcAckBusyChk_A, src_ack |-> src_busy_q, clk_src_i, !rst_src_ni) 84 85 1/1 assign src_busy_o = src_busy_q; Tests: T1 T2 T3  86 87 // src_q acts as both the write holding register and the software read back 88 // register. 89 // When software performs a write, the write data is captured in src_q for 90 // CDC purposes. When not performing a write, the src_q reflects the most recent 91 // hardware value. For registers with no hardware access, this is simply the 92 // the value programmed by software (or in the case R1C, W1C etc) the value after 93 // the operation. For registers with hardware access, this reflects a potentially 94 // delayed version of the real value, as the software facing updates lag real 95 // time updates. 96 // 97 // To resolve software and hardware conflicts, the process is as follows: 98 // When software issues a write, this module asserts "busy". While busy, 99 // src_q does not take on destination value updates. Since the 100 // logic has committed to updating based on software command, there is an irreversible 101 // window from which hardware writes are ignored. Once the busy window completes, 102 // the cdc portion then begins sampling once more. 103 // 104 // This is consistent with prim_subreg_arb where during software / hardware conflicts, 105 // software is always prioritized. The main difference is the conflict resolution window 106 // is now larger instead of just one destination clock cycle. 107 108 logic busy; 109 1/1 assign busy = src_busy_q & !src_ack; Tests: T1 T2 T3  110 111 // This is the current destination value 112 logic [DataWidth-1:0] dst_qs; 113 logic src_update; 114 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 115 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  116 1/1 src_q <= ResetVal; Tests: T1 T2 T3  117 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  118 1/1 end else if (src_req) begin Tests: T1 T2 T3  119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 1/1 src_q <= src_wd_i & BitMask; Tests: T1 T2 T3  124 1/1 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; Tests: T1 T2 T3  125 1/1 end else if (src_busy_q && src_ack || src_update && !busy) begin Tests: T1 T2 T3  126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 1/1 src_q <= dst_qs; Tests: T1 T2 T3  135 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  136 end MISSING_ELSE 137 end 138 139 // The current design (tlul_adapter_reg) does not spit out a request if the destination it chooses 140 // (decoded from address) is busy. So this creates a situation in the current design where 141 // src_req_i and busy can never be high at the same time. 142 // While the code above could be coded directly to be expressed as `src_req & !busy`, which makes 143 // the intent clearer, it ends up causing coverage holes from the tool's perspective since that 144 // condition cannot be met. 145 // Thus we add an assertion here to ensure the condition is always satisfied. 146 `ASSERT(BusySrcReqChk_A, busy |-> !src_req, clk_src_i, !rst_src_ni) 147 148 // reserved bits are not used 149 logic unused_wd; 150 1/1 assign unused_wd = ^src_wd_i; Tests: T1 T2 T3  151 152 // src_q is always updated in the clk_src domain. 153 // when performing an update to the destination domain, it is guaranteed 154 // to not change by protocol. 155 1/1 assign src_qs_o = src_q; Tests: T1 T2 T3  156 1/1 assign dst_wd_o = src_q; Tests: T1 T2 T3  157 158 //////////////////////////// 159 // CDC handling 160 //////////////////////////// 161 162 logic dst_req_from_src; 163 logic dst_req; 164 165 166 // the software transaction is pulse synced across the domain. 167 // the prim_reg_cdc_arb module handles conflicts with ongoing hardware updates. 168 prim_pulse_sync u_src_to_dst_req ( 169 .clk_src_i, 170 .rst_src_ni, 171 .clk_dst_i, 172 .rst_dst_ni, 173 .src_pulse_i(src_req), 174 .dst_pulse_o(dst_req_from_src) 175 ); 176 177 prim_reg_cdc_arb #( 178 .DataWidth(DataWidth), 179 .ResetVal(ResetVal), 180 .DstWrReq(DstWrReq) 181 ) u_arb ( 182 .clk_src_i, 183 .rst_src_ni, 184 .clk_dst_i, 185 .rst_dst_ni, 186 .src_ack_o(src_ack), 187 .src_update_o(src_update), 188 .dst_req_i(dst_req_from_src), 189 .dst_req_o(dst_req), 190 .dst_update_i, 191 .dst_ds_i, 192 .dst_qs_i, 193 .dst_qs_o(dst_qs) 194 ); 195 196 197 // Each is valid only when destination request pulse is high; this is important in not propagating 198 // the internal assertion of 'dst_req' by the 'prim_pulse_sync' channel when just one domain is 199 // reset. 200 1/1 assign {dst_we_o, dst_re_o, dst_regwen_o} = txn_bits_q & {TxnWidth{dst_req}}; Tests: T1 T2 T3 

Cond Coverage for Instance : tb.dut.u_reg.u_wkup_count_lo_cdc
TotalCoveredPercent
Conditions141392.86
Logical141392.86
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01CoveredT1,T2,T3
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT5,T7,T8
11CoveredT1,T2,T3

Branch Coverage for Instance : tb.dut.u_reg.u_wkup_count_lo_cdc
Line No.TotalCoveredPercent
Branches 8 8 100.00
IF 71 4 4 100.00
IF 115 4 4 100.00


71 if (!rst_src_ni) begin -1- 72 src_busy_q <= '0; ==> 73 end else if (src_req) begin -2- 74 src_busy_q <= 1'b1; ==> 75 end else if (src_ack) begin -3- 76 src_busy_q <= 1'b0; ==> 77 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


115 if (!rst_src_ni) begin -1- 116 src_q <= ResetVal; ==> 117 txn_bits_q <= '0; 118 end else if (src_req) begin -2- 119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 src_q <= src_wd_i & BitMask; ==> 124 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; 125 end else if (src_busy_q && src_ack || src_update && !busy) begin -3- 126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 src_q <= dst_qs; ==> 135 txn_bits_q <= '0; 136 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


Assert Coverage for Instance : tb.dut.u_reg.u_wkup_count_lo_cdc
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 4 4 100.00 4 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 4 4 100.00 4 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
BusySrcReqChk_A 622911264 4559197 0 0
DstReqKnown_A 2404804 2314984 0 0
SrcAckBusyChk_A 622911264 4295 0 0
SrcBusyKnown_A 622911264 622684546 0 0


BusySrcReqChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 4559197 0 0
T1 11325 854 0 0
T2 22349 2927 0 0
T3 14739 1425 0 0
T4 64450 1477 0 0
T5 39010 4068 0 0
T6 57759 3384 0 0
T7 287404 12856 0 0
T8 23380 3737 0 0
T9 0 1238 0 0
T10 0 4310 0 0
T11 84540 0 0 0
T12 102683 0 0 0

DstReqKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2404804 2314984 0 0
T1 97 23 0 0
T2 90 25 0 0
T3 116 28 0 0
T4 329 246 0 0
T5 83 14 0 0
T6 118 22 0 0
T7 2394 1829 0 0
T8 92 21 0 0
T11 804 12 0 0
T12 1710 53 0 0

SrcAckBusyChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 4295 0 0
T1 11325 2 0 0
T2 22349 3 0 0
T3 14739 3 0 0
T4 64450 2 0 0
T5 39010 2 0 0
T6 57759 2 0 0
T7 287404 25 0 0
T8 23380 3 0 0
T9 0 2 0 0
T10 0 2 0 0
T11 84540 0 0 0
T12 102683 0 0 0

SrcBusyKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 622684546 0 0
T1 11325 11230 0 0
T2 22349 22268 0 0
T3 14739 14678 0 0
T4 64450 64391 0 0
T5 39010 38959 0 0
T6 57759 57707 0 0
T7 287404 286880 0 0
T8 23380 23288 0 0
T11 84540 83790 0 0
T12 102683 101011 0 0

Line Coverage for Instance : tb.dut.u_reg.u_wdog_count_cdc
Line No.TotalCoveredPercent
TOTAL2222100.00
CONT_ASSIGN6511100.00
ALWAYS7166100.00
CONT_ASSIGN8511100.00
CONT_ASSIGN10911100.00
ALWAYS11599100.00
CONT_ASSIGN15011100.00
CONT_ASSIGN15511100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN20011100.00

64 65 1/1 assign src_req = src_we_i | src_re_i; Tests: T1 T2 T3  66 67 // busy indication back-pressures upstream if the register is accessed 68 // again. The busy indication is also used as a "commit" indication for 69 // resolving software and hardware write conflicts 70 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 71 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  72 1/1 src_busy_q <= '0; Tests: T1 T2 T3  73 1/1 end else if (src_req) begin Tests: T1 T2 T3  74 1/1 src_busy_q <= 1'b1; Tests: T1 T2 T3  75 1/1 end else if (src_ack) begin Tests: T1 T2 T3  76 1/1 src_busy_q <= 1'b0; Tests: T1 T2 T3  77 end MISSING_ELSE 78 end 79 80 // A src_ack should only be sent if there was a src_req. 81 // src_busy_q asserts whenever there is a src_req. By association, 82 // whenever src_ack is seen, then src_busy must be high. 83 `ASSERT(SrcAckBusyChk_A, src_ack |-> src_busy_q, clk_src_i, !rst_src_ni) 84 85 1/1 assign src_busy_o = src_busy_q; Tests: T1 T2 T3  86 87 // src_q acts as both the write holding register and the software read back 88 // register. 89 // When software performs a write, the write data is captured in src_q for 90 // CDC purposes. When not performing a write, the src_q reflects the most recent 91 // hardware value. For registers with no hardware access, this is simply the 92 // the value programmed by software (or in the case R1C, W1C etc) the value after 93 // the operation. For registers with hardware access, this reflects a potentially 94 // delayed version of the real value, as the software facing updates lag real 95 // time updates. 96 // 97 // To resolve software and hardware conflicts, the process is as follows: 98 // When software issues a write, this module asserts "busy". While busy, 99 // src_q does not take on destination value updates. Since the 100 // logic has committed to updating based on software command, there is an irreversible 101 // window from which hardware writes are ignored. Once the busy window completes, 102 // the cdc portion then begins sampling once more. 103 // 104 // This is consistent with prim_subreg_arb where during software / hardware conflicts, 105 // software is always prioritized. The main difference is the conflict resolution window 106 // is now larger instead of just one destination clock cycle. 107 108 logic busy; 109 1/1 assign busy = src_busy_q & !src_ack; Tests: T1 T2 T3  110 111 // This is the current destination value 112 logic [DataWidth-1:0] dst_qs; 113 logic src_update; 114 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 115 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  116 1/1 src_q <= ResetVal; Tests: T1 T2 T3  117 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  118 1/1 end else if (src_req) begin Tests: T1 T2 T3  119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 1/1 src_q <= src_wd_i & BitMask; Tests: T1 T2 T3  124 1/1 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; Tests: T1 T2 T3  125 1/1 end else if (src_busy_q && src_ack || src_update && !busy) begin Tests: T1 T2 T3  126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 1/1 src_q <= dst_qs; Tests: T1 T2 T3  135 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  136 end MISSING_ELSE 137 end 138 139 // The current design (tlul_adapter_reg) does not spit out a request if the destination it chooses 140 // (decoded from address) is busy. So this creates a situation in the current design where 141 // src_req_i and busy can never be high at the same time. 142 // While the code above could be coded directly to be expressed as `src_req & !busy`, which makes 143 // the intent clearer, it ends up causing coverage holes from the tool's perspective since that 144 // condition cannot be met. 145 // Thus we add an assertion here to ensure the condition is always satisfied. 146 `ASSERT(BusySrcReqChk_A, busy |-> !src_req, clk_src_i, !rst_src_ni) 147 148 // reserved bits are not used 149 logic unused_wd; 150 1/1 assign unused_wd = ^src_wd_i; Tests: T1 T2 T3  151 152 // src_q is always updated in the clk_src domain. 153 // when performing an update to the destination domain, it is guaranteed 154 // to not change by protocol. 155 1/1 assign src_qs_o = src_q; Tests: T1 T2 T3  156 1/1 assign dst_wd_o = src_q; Tests: T1 T2 T3  157 158 //////////////////////////// 159 // CDC handling 160 //////////////////////////// 161 162 logic dst_req_from_src; 163 logic dst_req; 164 165 166 // the software transaction is pulse synced across the domain. 167 // the prim_reg_cdc_arb module handles conflicts with ongoing hardware updates. 168 prim_pulse_sync u_src_to_dst_req ( 169 .clk_src_i, 170 .rst_src_ni, 171 .clk_dst_i, 172 .rst_dst_ni, 173 .src_pulse_i(src_req), 174 .dst_pulse_o(dst_req_from_src) 175 ); 176 177 prim_reg_cdc_arb #( 178 .DataWidth(DataWidth), 179 .ResetVal(ResetVal), 180 .DstWrReq(DstWrReq) 181 ) u_arb ( 182 .clk_src_i, 183 .rst_src_ni, 184 .clk_dst_i, 185 .rst_dst_ni, 186 .src_ack_o(src_ack), 187 .src_update_o(src_update), 188 .dst_req_i(dst_req_from_src), 189 .dst_req_o(dst_req), 190 .dst_update_i, 191 .dst_ds_i, 192 .dst_qs_i, 193 .dst_qs_o(dst_qs) 194 ); 195 196 197 // Each is valid only when destination request pulse is high; this is important in not propagating 198 // the internal assertion of 'dst_req' by the 'prim_pulse_sync' channel when just one domain is 199 // reset. 200 1/1 assign {dst_we_o, dst_re_o, dst_regwen_o} = txn_bits_q & {TxnWidth{dst_req}}; Tests: T1 T2 T3 

Cond Coverage for Instance : tb.dut.u_reg.u_wdog_count_cdc
TotalCoveredPercent
Conditions141392.86
Logical141392.86
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01CoveredT7,T13,T23
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT5,T7,T16
11CoveredT7,T13,T23

Branch Coverage for Instance : tb.dut.u_reg.u_wdog_count_cdc
Line No.TotalCoveredPercent
Branches 8 8 100.00
IF 71 4 4 100.00
IF 115 4 4 100.00


71 if (!rst_src_ni) begin -1- 72 src_busy_q <= '0; ==> 73 end else if (src_req) begin -2- 74 src_busy_q <= 1'b1; ==> 75 end else if (src_ack) begin -3- 76 src_busy_q <= 1'b0; ==> 77 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


115 if (!rst_src_ni) begin -1- 116 src_q <= ResetVal; ==> 117 txn_bits_q <= '0; 118 end else if (src_req) begin -2- 119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 src_q <= src_wd_i & BitMask; ==> 124 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; 125 end else if (src_busy_q && src_ack || src_update && !busy) begin -3- 126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 src_q <= dst_qs; ==> 135 txn_bits_q <= '0; 136 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


Assert Coverage for Instance : tb.dut.u_reg.u_wdog_count_cdc
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 4 4 100.00 4 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 4 4 100.00 4 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
BusySrcReqChk_A 622911264 4242992 0 0
DstReqKnown_A 2404804 2314984 0 0
SrcAckBusyChk_A 622911264 4260 0 0
SrcBusyKnown_A 622911264 622684546 0 0


BusySrcReqChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 4242992 0 0
T1 11325 713 0 0
T2 22349 2671 0 0
T3 14739 1363 0 0
T4 64450 1429 0 0
T5 39010 4034 0 0
T6 57759 2890 0 0
T7 287404 10957 0 0
T8 23380 3226 0 0
T9 0 730 0 0
T10 0 3341 0 0
T11 84540 0 0 0
T12 102683 0 0 0

DstReqKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2404804 2314984 0 0
T1 97 23 0 0
T2 90 25 0 0
T3 116 28 0 0
T4 329 246 0 0
T5 83 14 0 0
T6 118 22 0 0
T7 2394 1829 0 0
T8 92 21 0 0
T11 804 12 0 0
T12 1710 53 0 0

SrcAckBusyChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 4260 0 0
T1 11325 2 0 0
T2 22349 3 0 0
T3 14739 3 0 0
T4 64450 2 0 0
T5 39010 2 0 0
T6 57759 2 0 0
T7 287404 25 0 0
T8 23380 3 0 0
T9 0 2 0 0
T10 0 2 0 0
T11 84540 0 0 0
T12 102683 0 0 0

SrcBusyKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 622684546 0 0
T1 11325 11230 0 0
T2 22349 22268 0 0
T3 14739 14678 0 0
T4 64450 64391 0 0
T5 39010 38959 0 0
T6 57759 57707 0 0
T7 287404 286880 0 0
T8 23380 23288 0 0
T11 84540 83790 0 0
T12 102683 101011 0 0

Line Coverage for Instance : tb.dut.u_reg.u_wkup_cause_cdc
Line No.TotalCoveredPercent
TOTAL2222100.00
CONT_ASSIGN6511100.00
ALWAYS7166100.00
CONT_ASSIGN8511100.00
CONT_ASSIGN10911100.00
ALWAYS11599100.00
CONT_ASSIGN15011100.00
CONT_ASSIGN15511100.00
CONT_ASSIGN15611100.00
CONT_ASSIGN20011100.00

64 65 1/1 assign src_req = src_we_i | src_re_i; Tests: T1 T2 T3  66 67 // busy indication back-pressures upstream if the register is accessed 68 // again. The busy indication is also used as a "commit" indication for 69 // resolving software and hardware write conflicts 70 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 71 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  72 1/1 src_busy_q <= '0; Tests: T1 T2 T3  73 1/1 end else if (src_req) begin Tests: T1 T2 T3  74 1/1 src_busy_q <= 1'b1; Tests: T1 T2 T3  75 1/1 end else if (src_ack) begin Tests: T1 T2 T3  76 1/1 src_busy_q <= 1'b0; Tests: T1 T2 T3  77 end MISSING_ELSE 78 end 79 80 // A src_ack should only be sent if there was a src_req. 81 // src_busy_q asserts whenever there is a src_req. By association, 82 // whenever src_ack is seen, then src_busy must be high. 83 `ASSERT(SrcAckBusyChk_A, src_ack |-> src_busy_q, clk_src_i, !rst_src_ni) 84 85 1/1 assign src_busy_o = src_busy_q; Tests: T1 T2 T3  86 87 // src_q acts as both the write holding register and the software read back 88 // register. 89 // When software performs a write, the write data is captured in src_q for 90 // CDC purposes. When not performing a write, the src_q reflects the most recent 91 // hardware value. For registers with no hardware access, this is simply the 92 // the value programmed by software (or in the case R1C, W1C etc) the value after 93 // the operation. For registers with hardware access, this reflects a potentially 94 // delayed version of the real value, as the software facing updates lag real 95 // time updates. 96 // 97 // To resolve software and hardware conflicts, the process is as follows: 98 // When software issues a write, this module asserts "busy". While busy, 99 // src_q does not take on destination value updates. Since the 100 // logic has committed to updating based on software command, there is an irreversible 101 // window from which hardware writes are ignored. Once the busy window completes, 102 // the cdc portion then begins sampling once more. 103 // 104 // This is consistent with prim_subreg_arb where during software / hardware conflicts, 105 // software is always prioritized. The main difference is the conflict resolution window 106 // is now larger instead of just one destination clock cycle. 107 108 logic busy; 109 1/1 assign busy = src_busy_q & !src_ack; Tests: T1 T2 T3  110 111 // This is the current destination value 112 logic [DataWidth-1:0] dst_qs; 113 logic src_update; 114 always_ff @(posedge clk_src_i or negedge rst_src_ni) begin 115 1/1 if (!rst_src_ni) begin Tests: T1 T2 T3  116 1/1 src_q <= ResetVal; Tests: T1 T2 T3  117 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  118 1/1 end else if (src_req) begin Tests: T1 T2 T3  119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 1/1 src_q <= src_wd_i & BitMask; Tests: T1 T2 T3  124 1/1 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; Tests: T1 T2 T3  125 1/1 end else if (src_busy_q && src_ack || src_update && !busy) begin Tests: T1 T2 T3  126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 1/1 src_q <= dst_qs; Tests: T1 T2 T3  135 1/1 txn_bits_q <= '0; Tests: T1 T2 T3  136 end MISSING_ELSE 137 end 138 139 // The current design (tlul_adapter_reg) does not spit out a request if the destination it chooses 140 // (decoded from address) is busy. So this creates a situation in the current design where 141 // src_req_i and busy can never be high at the same time. 142 // While the code above could be coded directly to be expressed as `src_req & !busy`, which makes 143 // the intent clearer, it ends up causing coverage holes from the tool's perspective since that 144 // condition cannot be met. 145 // Thus we add an assertion here to ensure the condition is always satisfied. 146 `ASSERT(BusySrcReqChk_A, busy |-> !src_req, clk_src_i, !rst_src_ni) 147 148 // reserved bits are not used 149 logic unused_wd; 150 1/1 assign unused_wd = ^src_wd_i; Tests: T1 T2 T3  151 152 // src_q is always updated in the clk_src domain. 153 // when performing an update to the destination domain, it is guaranteed 154 // to not change by protocol. 155 1/1 assign src_qs_o = src_q; Tests: T1 T2 T3  156 1/1 assign dst_wd_o = src_q; Tests: T1 T2 T3  157 158 //////////////////////////// 159 // CDC handling 160 //////////////////////////// 161 162 logic dst_req_from_src; 163 logic dst_req; 164 165 166 // the software transaction is pulse synced across the domain. 167 // the prim_reg_cdc_arb module handles conflicts with ongoing hardware updates. 168 prim_pulse_sync u_src_to_dst_req ( 169 .clk_src_i, 170 .rst_src_ni, 171 .clk_dst_i, 172 .rst_dst_ni, 173 .src_pulse_i(src_req), 174 .dst_pulse_o(dst_req_from_src) 175 ); 176 177 prim_reg_cdc_arb #( 178 .DataWidth(DataWidth), 179 .ResetVal(ResetVal), 180 .DstWrReq(DstWrReq) 181 ) u_arb ( 182 .clk_src_i, 183 .rst_src_ni, 184 .clk_dst_i, 185 .rst_dst_ni, 186 .src_ack_o(src_ack), 187 .src_update_o(src_update), 188 .dst_req_i(dst_req_from_src), 189 .dst_req_o(dst_req), 190 .dst_update_i, 191 .dst_ds_i, 192 .dst_qs_i, 193 .dst_qs_o(dst_qs) 194 ); 195 196 197 // Each is valid only when destination request pulse is high; this is important in not propagating 198 // the internal assertion of 'dst_req' by the 'prim_pulse_sync' channel when just one domain is 199 // reset. 200 1/1 assign {dst_we_o, dst_re_o, dst_regwen_o} = txn_bits_q & {TxnWidth{dst_req}}; Tests: T1 T2 T3 

Cond Coverage for Instance : tb.dut.u_reg.u_wkup_cause_cdc
TotalCoveredPercent
Conditions161593.75
Logical161593.75
Non-Logical00
Event00

 LINE       65
 EXPRESSION (src_we_i | src_re_i)
             ----1---   ----2---
-1--2-StatusTests
00CoveredT1,T2,T3
01Unreachable
10CoveredT1,T2,T3

 LINE       109
 EXPRESSION (src_busy_q & ((!src_ack)))
             -----1----   ------2-----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       123
 EXPRESSION (src_wd_i & BitMask)
             ----1---   ---2---
-1--2-StatusTests
0-CoveredT1,T2,T3
1-CoveredT38,T39,T40

 LINE       125
 EXPRESSION ((src_busy_q && src_ack) || (src_update && ((!busy))))
             -----------1-----------    ------------2------------
-1--2-StatusTests
00CoveredT1,T2,T3
01CoveredT1,T2,T3
10CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_busy_q && src_ack)
                 -----1----    ---2---
-1--2-StatusTests
01Not Covered
10CoveredT1,T2,T3
11CoveredT1,T2,T3

 LINE       125
 SUB-EXPRESSION (src_update && ((!busy)))
                 -----1----    ----2----
-1--2-StatusTests
01CoveredT1,T2,T3
10CoveredT7,T36,T37
11CoveredT1,T2,T3

Branch Coverage for Instance : tb.dut.u_reg.u_wkup_cause_cdc
Line No.TotalCoveredPercent
Branches 8 8 100.00
IF 71 4 4 100.00
IF 115 4 4 100.00


71 if (!rst_src_ni) begin -1- 72 src_busy_q <= '0; ==> 73 end else if (src_req) begin -2- 74 src_busy_q <= 1'b1; ==> 75 end else if (src_ack) begin -3- 76 src_busy_q <= 1'b0; ==> 77 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


115 if (!rst_src_ni) begin -1- 116 src_q <= ResetVal; ==> 117 txn_bits_q <= '0; 118 end else if (src_req) begin -2- 119 // See assertion below 120 // At the beginning of a software initiated transaction, the following 121 // values are captured in the src_q/txn_bits_q flops to ensure they cannot 122 // change for the duration of the synchronization operation. 123 src_q <= src_wd_i & BitMask; ==> 124 txn_bits_q <= {src_we_i, src_re_i, src_regwen_i}; 125 end else if (src_busy_q && src_ack || src_update && !busy) begin -3- 126 // sample data whenever a busy transaction finishes OR 127 // when an update pulse is seen. 128 // TODO: We should add a cover group to test different sync timings 129 // between src_ack and src_update. ie. there can be 3 scenarios: 130 // 1. update one cycle before ack 131 // 2. ack one cycle before update 132 // 3. update / ack on the same cycle 133 // During all 3 cases the read data should be correct 134 src_q <= dst_qs; ==> 135 txn_bits_q <= '0; 136 end MISSING_ELSE ==>

Branches:
-1--2--3-StatusTests
1 - - Covered T1,T2,T3
0 1 - Covered T1,T2,T3
0 0 1 Covered T1,T2,T3
0 0 0 Covered T1,T2,T3


Assert Coverage for Instance : tb.dut.u_reg.u_wkup_cause_cdc
TotalAttemptedPercentSucceeded/MatchedPercent
Assertions 4 4 100.00 4 100.00
Cover properties 0 0 0
Cover sequences 0 0 0
Total 4 4 100.00 4 100.00




Assertion Details

NameAttemptsReal SuccessesFailuresIncomplete
BusySrcReqChk_A 622911264 1882460 0 0
DstReqKnown_A 2404804 2314984 0 0
SrcAckBusyChk_A 622911264 1932 0 0
SrcBusyKnown_A 622911264 622684546 0 0


BusySrcReqChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 1882460 0 0
T1 11325 310 0 0
T2 22349 730 0 0
T3 14739 454 0 0
T4 64450 747 0 0
T5 39010 2265 0 0
T6 57759 1449 0 0
T7 287404 5105 0 0
T8 23380 995 0 0
T9 0 369 0 0
T10 0 1914 0 0
T11 84540 0 0 0
T12 102683 0 0 0

DstReqKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 2404804 2314984 0 0
T1 97 23 0 0
T2 90 25 0 0
T3 116 28 0 0
T4 329 246 0 0
T5 83 14 0 0
T6 118 22 0 0
T7 2394 1829 0 0
T8 92 21 0 0
T11 804 12 0 0
T12 1710 53 0 0

SrcAckBusyChk_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 1932 0 0
T1 11325 1 0 0
T2 22349 1 0 0
T3 14739 1 0 0
T4 64450 1 0 0
T5 39010 1 0 0
T6 57759 1 0 0
T7 287404 10 0 0
T8 23380 1 0 0
T9 0 1 0 0
T10 0 1 0 0
T11 84540 0 0 0
T12 102683 0 0 0

SrcBusyKnown_A
NameAttemptsReal SuccessesFailuresIncomplete
Total 622911264 622684546 0 0
T1 11325 11230 0 0
T2 22349 22268 0 0
T3 14739 14678 0 0
T4 64450 64391 0 0
T5 39010 38959 0 0
T6 57759 57707 0 0
T7 287404 286880 0 0
T8 23380 23288 0 0
T11 84540 83790 0 0
T12 102683 101011 0 0

0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100%