资料介绍
SystemVerilog Assertion Handbook1 ROLE OF SYSTEMVERILOG ASSERTIONS
IN A VERIFICATION METHODOLOGY .... 1
1.1 History of Design Verification methodologies ....…… 2
1.2 SystemVerilog Assertions in verification Strategy ..……... 5
1.2.1 Are Assertions Independent from SystemVerilog Structures? 5
1.2.2 Are Assertions Useful for the Definition and Verification of Designs? ….. 6
1.2.2.1 Captures Designer Intent 7
1.2.2.2 Allows Protocols to be Defined and Verified . 8
1.2.2.3 Reduces the Time to Market ....…. 8
1.2.2.4 Greatly Simplifies the Verification of Reusable IP .. 8
1.2.2.5 Facilitates Functional Coverage Metrics .... 9
1.2.2.6 Generates Counterexamples to Demonstrate Violation of Properties … 10
1.2.3 Can/should entire functional verification task be performed
using SystemVerilog Assertions? ....…. 10
1.2.4 Is SystemVerilog Assertions Solely Restricted to Applications that
Use SystemVerilog? .…. 10
1.2.4.1 VHDL Model and Testbench with SystemVerilog Assertions Module 10
1.2.4.2 VHDL Model Embedded in SystemVerilog testbench with SVA Module . 11
1.3 Accellera's SystemVerilog Assertions Goals ……. 11
1.4 SystemVerilog Assertions Language …… 12
2 OVERVIEW OF PROPERTIES AND ASSERTIONS ..………. 15
2.1 DEFINITIONS .…………… 15
2.1.1 Properties .……. 15
2.1.2 Sequences ……. 16
2.1.3 Antecedent / Consequent / Thread …. 16
2.1.4 Specification and Verification .…… 18
Assertion-Based Verification .. 18
2.1.5 Assertion / Assumption / Verification Directive ……….. 19
2.1.6 Constraint …… 19
2.2 property ……….. 20
2.2.1 Named Properties …... 20
2.3 Assertion ……….. 21
2.3.1 Immediate assertions .. 22
2.3.2 Concurrent Assertion 24
Verification Directives 24
2.4 Boolean Expression ……… 26
3 UNDERSTANDING PROPERTIES 27
3.1 Sequences Overview ……. 28
3.1.1 Sequence Declaration 29
3.2 SystemVerilog Properties ……… 31
3.2.1 Property Header ……… 32
3.2.2 Property Identifier ……. 33
3.2.3 Formal Arguments and Usage 33
3.2.4 Local Variables in Properties .. 34
3.2.5 Body of the Property .. 39
3.2.5.1 Clocking Event ……… 39
3.2.5.2 Disabling condition ….. 40
3.2.5.3 Property Expression … 42
3.2.5.3.1 Property Operators 42
4 UNDERSTANDING SEQUENCES ....….. 47
4.1 Sequence Operators and Built-in Functions …… 48
4.2 Capturing Temporal Behavior in SystemVerilog Assertions …… 49
4.3 Implication Operators ...…. 53
4.3.1 Overlapped implication Operator |-> . 54
4.3.2 Non Overlapped Implication Operator |=> ….. 55
4.3.3 Understanding the Overlapped Implication Operator "|->" ....….. 56
4.3.4 Understanding the Non-overlapped Implication Operator " |=>" ....…… 58
4.3.5 Using "not" with Implication Operator ....……… 59
4.4 first_match Operator ....….. 60
4.5 Repetition Operators ....….. 64
4.5.1 Consecutive Repetition .. 66
4.5.1.1 [*n] Repetition ... 66
4.5.1.2 [*n:m] Repetition ....…… 66
4.5.1.3 [*0 : m] Repetitions ....…. 69
4.5.1.4 [*n : $], ##[0:$] … 71
4.5.2 Sequence Non-consecutive Repetition ([=n]) ....…. 74
4.5.3 Sequence goto Repetition ([->n ]) ...……. 74
4.6 Sequence Composition Operators ...……….. 75
4.6.1 Sequence Fusion (##0) .... 76
4.6.2 Sequence Disjunction (or) ....…… 76
4.6.3 Sequence Non-Length-Matching (and) ....………. 77
4.6.4 Sequence Length-Matching (intersect) .… 77
4.6.5 Sequence Containment (within) ..……… 78
4.6.6 Conditions over Sequences (throughout operator) ...……. 79
4.7 Methods Supporting Sequences ..………… 80
4.7.1 Endpoint of a Single Clock Sequence "ended" . 80
4.7.2 Endpoint of a Multi-Clock Sequence "matched" ...…… 83
4.7.3 Triggered Method ...…… 84
4.7.4 Sequence events ...……….. 85
Exercises .... 86
5 Advanced Topics For Properties and Sequences ....……. 91
5.1 Data types in Properties and Sequences ..………….. 91
5.2 Misuse of Assertion Overlapping .…………. 93
5.3 Multiple Threads Termination .…………. 98
5.4 Assertion Refinement Process ….. 99
5.4.1 Relaxed, stringent assertion ….. 100
5.5 Unbounded Range $ in Properties ....………… 100
5.6 Recursion ..…………. 101
5.7 Emulating PSL-Like Constructs in SVA ...…………. 104
5.7.1 whilenot ……… 104
5.7.2 The eventually! Operator in Sequence …. 106
5.7.3 Emulating UNTIL with Sequences ....……. 106
5.7.4 F before G …….. 107
5.7.5 One-Shot Assertion Using Initial blocks ………. 108
5.7.5.1 Flag Bit Defining Start of Antecedent . 108
5.7.5.2 Procedural Assertion in Initial Block . 109
5.8 Assertion-Based System Functions ....…….. 109
5.8.1 Sampled Valued Functions ….. 109
5.8.1.1 Value access functions .. 109
5.8.1.1.1 $sampled(expression [, clocking_event]) …………… 110
5.8.1.1.2 $past ……… 111
5.8.1.2 Value change functions ………. 113
5.8.1.2.1 $rose and $fell ……… 113
5.8.1.2.2 $stable ……… 115
5.8.2 Vector-Analysis System Functions ...…… 116
5.8.3 Severity-level System Functions ...………… 116
5.8.4 Assertion-Control System Tasks ...………. 117
5.9 Clocked Sequence and Multi-Clocking ....……………. 118
5.9.1 Clock Specification for Properties and Sequences ...……. 118
5.9.2 Clock Resolution ..…….. 120
5.9.2.1 Clock Resolution in Assertion and Property Directives ....………. 121
5.9.2.2 Clock Resolution in Sequences .. 121
5.9.3 Multiple clocked sequences ...……. 123
5.9.3.1 Rules in Using Multiple-Clocked Sequence ...…... 125
5.9.4 Multiple-clocked properties ...……. 127
5.9.5 Clock flow ..……… 128
5.9.6 Clocking Rules in Assertions ..….. 129
5.9.6.1 Single clocked assertions: ...……… 130
5.9.6.2 Sequence and Properties in Clocking Blocks ....…. 130
5.9.6.3 Multiple-clocked Assertions ...…… 131
5.10 SystemVerilog Scheduling semantics for Assertions ....….. 131
5.11 Properties in Interfaces ...………. 134
5.12 Verification Directives ....…. 135
5.12.1 assert Directive .……….. 135
5.12.1.1 Concurrent Assertion Statements Outside of Procedural Code ....……. 135
5.12.1.2 Concurrent Assertion Statements Embedded in Procedural Block 136
5.12.1.3 Immediate assertion: . 137
5.12.1.4 Action-block . 137
5.12.2 assume Directive ..……. 138
5.12.3 cover Directive . 140
5.12.4 Expect Construct ..…… 142
5.13 Binding Properties to Scopes or Instances ....…… 143
5.14 Verifying VHDL Models with SystemVerilog Assertions ....……… 148
5.14.1 The Concept ..….. 148
5.14.2 VHDL Module in VHDL Testbench with SystemVerilog Assertions Module . 148
5.14.2.1 VHDL Model ... 149
5.14.2.2 SystemVerilog Assertions Module 149
5.14.2.3 Connecting SystemVerilog Assertions module to VHDL design ....…… 150
5.14.2.3.1 Direct Instantiation of SVA module into VHDL Testbench .... 150
5.14.2.3.2 Binding of SVA Verification Module to VHDL Model ....…… 151
5.14.3 VHDL Model in a SystemVerilog Testbench with SVA Module ....……….. 152
6 SystemVerilog Assertions In the Design Process … 153
6.1 Traditional Design Process ……….. 154
6.2 Design Process with ABV using SVA as vehicle ………… 154
6.2.1 System-level Assertions ...………... 155
6.2.2 Interface Assertions …. 161
6.2.3 Architectural Plan ……. 161
6.2.4 Verification Plan …….. 162
6.2.5 RTL Design ..……. 163
6.2.6 Write Testbench and Simulate . 164
6.2.7 Analyze the Simulation Results and Coverage 164
6.2.8 Formal Verification (FV) …… 169
6.3 Case Study - Synchronous FIFO ....……….. 170
6.3.1 Synchronous FIFO Requirements ....…… 170
6.3.2 Verification Plan …….. 182
6.3.3 RTL Design ..…... 191
6.3.4 Simulation ……. 193
6.3.5 Formal Verification ..……. 193
Exercises .. 195
7 FORMAL VERIFICATION USING ASSERTIONS .. 199
7.1 FV METHODOLOGY ………….. 200
7.1.1 Model Checking Expectations and Rules . ….. 203
7.2 Role of SystemVerilog Assertions in FV ………… 204
7.2.1 SystemVerilog Assertions in Formal Specifications …. 204
7.2.2 SystemVerilog Assertions Usage in FV vs. Dynamic ABV …… 205
7.2.2.1 Same Inputs in Antecedent and Consequent ..….. 205
7.3 CASE STUDY - FV OF A TRAFFIC LIGHT CONTROLLER …………. 206
7.3.1 Model … 206
7.3.2 Basic requirements .…… 209
7.3.3 SystemVerilog Assertions for Traffic Light Controller .……… 209
7.3.4 Verification .…. 213
7.3.5 Good Traffic Light Controller 215
7.4 FV COVERAGE METRICS .…….. 216
7.4.1 Proof Radius ... 216
7.4.2 Explored State-Based Coverage …….. 217
7.4.3 Flip-flop to Property Distance 217
7.4.4 Functional Coverage Points .…. 217
7.5 EMERGING APPLICATIONS OF SYSTEMVERILOG ASSERTIONS
WITH FORMAL METHODS 217
7.5.1 SystemVerilog Assertions Based Performance Evaluation of Digital Systems 217
7.5.2 Hybrid (dynamic and formal) Verification .…. 218
7.5.3 Directed Random Test Generation from SystemVerilog Assertions .… 219
7.5.4 Achieving hard-to-hit functional coverage goals using Formal Methods ……. 219
7.6 Temporal Debugging .……. 222
7.7 SIMULATION OR FORMAL VERIFICATION? ………. 224
7.7.1 Arguments for Simulation with ABV .. 224
7.7.2 Arguments for Formal Verification …. 225
7.7.3 Balance .……….. 225
7.7.4 Recommendations .……. 226
7.7.5 Validity of Formal Verification results .……….. 226
8 SystemVerilog Assertions Guidelines .…. 229
8.1 Typographic Guidelines .…………. 230
8.1.1 Naming Convention …. 230
8.1.1.1 File naming ……………. 230
8.1.1.2 Object Naming ………. 230
8.1.1.3 Naming of Assertion Constructs ……………. 231
8.1.2 Ending Statements …… 231
8.1.3 Constants for Modules and Interfaces ……. 232
8.2 Use Model Guidelines … 232
8.2.1 Where to Write Properties and Assertions … 232
8.2.2 Assertions for Accuracy ……………….……… 234
8.2.2.1 Abide by Good Verilog Coding Style Rules . 234
8.2.2.2 Avoid Nested System Functions ……………. 234
8.2.2.3 Beware of unsized additions in +1 versus +1'b1 ………… 235
8.2.2.4 Beware of Property Negation Operator ….. 237
8.2.2.5 Ensure "Write before Read" while using Local Assertion Variables ………….. 238
8.2.2.6 Be Aware of Overlapping Assertions ………. 238
8.2.2.7 Beware of Metalogical Values ……………. 239
8.2.2.8 Avoid Vacuous Properties …………………. 239
8.2.2.9 Avoid Contradictory Properties ……….…… 239
8.2.3 Use $sampled Function in Action Block to Display Values of Current Variables 240
8.2.4 Accessing Local Variables in Assertions ……… 240
8.2.5 Style ….… 240
8.2.5.1 Avoid Unbounded Ranges …………………… 240
8.2.5.2 Use of Default Clock … 241
8.2.5.3 Evaluate Assertion Relative to a Clock ……… 241
8.2.5.4 Handling Resets in Properties ……………… 241
8.2.5.5 Defining Time Unit and Time Format Specifications for Design ………………… 242
8.2.5.6 Direct or Implicit Declaration of Properties . 245
8.2.5.7 Use Formal Arguments only when Reuse is Intended …… 246
8.2.5.8 Use module ports or Registered Signals in Properties …… 246
8.2.5.9 Standardize Action Block Error Display …… 247
8.2.5.10 Use generate Construct for Assertions Conditional on Parameters ………… 247
8.2.5.11 Use Pattern Format in Documenting Assertions ……… 248
8.2.5.12 Review Properties and Assertions Against Requirements ……………………. 248
8.2.5.13 Simulate Design … 248
8.2.5.14 Guidelines for Debugging Assertions …. 249
8.2.6 Using SystemVerilog assertions with Verilog RTL …………. 249
8.2.7 Using Dynamic Data Types inside Properties 250
8.3 Methodology Guidelines …. 251
8.3.1 Identifying Properties from Design Specifications ……….… 251
8.3.2 Classification of properties ………………….. 251
8.3.2.1 Design Centric . ……… 251
8.3.2.1.1 Style in FSM properties …………………… 251
8.3.2.2 Assumption Centric ….. 253
8.3.2.3 Requirement / Verification Centric ………… 253
8.3.2.4 Environmental Properties …………………. 254
8.3.2.5 Coverage Properties … 255
8.3.3 Process of Writing Properties and Assertions ……………... 256
9 SystemVerilog Assertions Dictionary 261
9.1 If COND1, then COND2 . 262
9.2 If COND1, then at next COND2, COND3 ……… 262
9.3 If COND1, then after nth COND2, COND3 ……. 263
9.4 If COND1 and first COND2, then COND3 until COND4 …….. 264
9.5 If COND1 and first COND2, then sequence ……… 264
9.6 Between COND1 and COND2, Signal 1 asserted .. 265
9.7 If COND1 and then 1 occurrence of COND2 then sequence ….. 266
9.8 If COND1 then N Occurrences of COND2 before COND3. N is value of signal …… 266
9.9 If COND1 and within n cycles y occurrences of COND2, then COND3 ……………….. 268
9.10 If COND1, then COND2 until COND3 ……… 269
9.11 If Cond1 then Cond2 before Cond3 …………. 269
9.12 If COND1 is followed by COND2, and COND3 is not received within 64 cycles while
COND2 then Error (COND5). If COND3 is received within 64 cycles then COND4 ……. 269
9.13 For every write (COND1), data transfers must alternate between
odd and even entries …… 271
9.14 If COND1 then COND2 in N cycles unless COND3 ………… 271
9.15 Data Integrity in Memory. Data read from Memory should be same as
what was last written …. 273
9.16 Data Integrity in QUEUES. Interface Data Written must be properly
transferred to the Receiving Hardware ……….. 274
9.17 Never 2 consecutive Writes with same Address ……………. 276
9.18 Cache controller requirement: A cached address (COND1) will eventually
be retired (COND2) and after that, within 2 to 7 clocks the cache
copy shall be invalidated (COND3) ………….. 277
9.19 during cond1 Never COND3 after COND2. Cond2 may occur within
n cycles after Cond1 …. 278
9.20 If COND1, then next N cycles COND2. If new COND1 before end of COND2,
then COND2 extended for N cycles until no COND1 ………. 278
9.21 Never two CONDs within 2 cycles Apart ……. 280
9.22 Assume Reset low for initial N cycles ………… 281
9.23 If COND1 and N cycle later COND2, then COND3 until COND4, unless COND5 .. 282
9.24 If Sequence COND1 followed by N non-necessarily consecutive COND2,
then N consecutive COND3 until COND4 …… 283
9.25 If COND1, COND2 doesn't change for N clocks, unless COND1 goes high again 283
9.26 If a Sequence Starts but does not Complete, then State Register must be in
ERROR state …………. 284
9.27 COND1 and COND2 are Mutually Exclusive .. 286
9.28 If Address Error, then eventually good address …………… 287
9.29 Enabling a property after a trigger ………….. 288
6 Appendix A Answers to Exercises ……. 289
A.1 Answers to Chapter 4 Exercises …………………. 289
A.2 Answers to Chapter 6 Exercise …………………. 298
Appendix B: Definitions 305
APPENDIX C: QUICK REFERENCE GUIDE ……… 313
APPENDIX D: CLOCK RESOLUTION .. 317
APPENDIX E: SYSTEMVERILOG ASSERTIONS SYNTAX ………. 321
Index ………… 325
IN A VERIFICATION METHODOLOGY .... 1
1.1 History of Design Verification methodologies ....…… 2
1.2 SystemVerilog Assertions in verification Strategy ..……... 5
1.2.1 Are Assertions Independent from SystemVerilog Structures? 5
1.2.2 Are Assertions Useful for the Definition and Verification of Designs? ….. 6
1.2.2.1 Captures Designer Intent 7
1.2.2.2 Allows Protocols to be Defined and Verified . 8
1.2.2.3 Reduces the Time to Market ....…. 8
1.2.2.4 Greatly Simplifies the Verification of Reusable IP .. 8
1.2.2.5 Facilitates Functional Coverage Metrics .... 9
1.2.2.6 Generates Counterexamples to Demonstrate Violation of Properties … 10
1.2.3 Can/should entire functional verification task be performed
using SystemVerilog Assertions? ....…. 10
1.2.4 Is SystemVerilog Assertions Solely Restricted to Applications that
Use SystemVerilog? .…. 10
1.2.4.1 VHDL Model and Testbench with SystemVerilog Assertions Module 10
1.2.4.2 VHDL Model Embedded in SystemVerilog testbench with SVA Module . 11
1.3 Accellera's SystemVerilog Assertions Goals ……. 11
1.4 SystemVerilog Assertions Language …… 12
2 OVERVIEW OF PROPERTIES AND ASSERTIONS ..………. 15
2.1 DEFINITIONS .…………… 15
2.1.1 Properties .……. 15
2.1.2 Sequences ……. 16
2.1.3 Antecedent / Consequent / Thread …. 16
2.1.4 Specification and Verification .…… 18
Assertion-Based Verification .. 18
2.1.5 Assertion / Assumption / Verification Directive ……….. 19
2.1.6 Constraint …… 19
2.2 property ……….. 20
2.2.1 Named Properties …... 20
2.3 Assertion ……….. 21
2.3.1 Immediate assertions .. 22
2.3.2 Concurrent Assertion 24
Verification Directives 24
2.4 Boolean Expression ……… 26
3 UNDERSTANDING PROPERTIES 27
3.1 Sequences Overview ……. 28
3.1.1 Sequence Declaration 29
3.2 SystemVerilog Properties ……… 31
3.2.1 Property Header ……… 32
3.2.2 Property Identifier ……. 33
3.2.3 Formal Arguments and Usage 33
3.2.4 Local Variables in Properties .. 34
3.2.5 Body of the Property .. 39
3.2.5.1 Clocking Event ……… 39
3.2.5.2 Disabling condition ….. 40
3.2.5.3 Property Expression … 42
3.2.5.3.1 Property Operators 42
4 UNDERSTANDING SEQUENCES ....….. 47
4.1 Sequence Operators and Built-in Functions …… 48
4.2 Capturing Temporal Behavior in SystemVerilog Assertions …… 49
4.3 Implication Operators ...…. 53
4.3.1 Overlapped implication Operator |-> . 54
4.3.2 Non Overlapped Implication Operator |=> ….. 55
4.3.3 Understanding the Overlapped Implication Operator "|->" ....….. 56
4.3.4 Understanding the Non-overlapped Implication Operator " |=>" ....…… 58
4.3.5 Using "not" with Implication Operator ....……… 59
4.4 first_match Operator ....….. 60
4.5 Repetition Operators ....….. 64
4.5.1 Consecutive Repetition .. 66
4.5.1.1 [*n] Repetition ... 66
4.5.1.2 [*n:m] Repetition ....…… 66
4.5.1.3 [*0 : m] Repetitions ....…. 69
4.5.1.4 [*n : $], ##[0:$] … 71
4.5.2 Sequence Non-consecutive Repetition ([=n]) ....…. 74
4.5.3 Sequence goto Repetition ([->n ]) ...……. 74
4.6 Sequence Composition Operators ...……….. 75
4.6.1 Sequence Fusion (##0) .... 76
4.6.2 Sequence Disjunction (or) ....…… 76
4.6.3 Sequence Non-Length-Matching (and) ....………. 77
4.6.4 Sequence Length-Matching (intersect) .… 77
4.6.5 Sequence Containment (within) ..……… 78
4.6.6 Conditions over Sequences (throughout operator) ...……. 79
4.7 Methods Supporting Sequences ..………… 80
4.7.1 Endpoint of a Single Clock Sequence "ended" . 80
4.7.2 Endpoint of a Multi-Clock Sequence "matched" ...…… 83
4.7.3 Triggered Method ...…… 84
4.7.4 Sequence events ...……….. 85
Exercises .... 86
5 Advanced Topics For Properties and Sequences ....……. 91
5.1 Data types in Properties and Sequences ..………….. 91
5.2 Misuse of Assertion Overlapping .…………. 93
5.3 Multiple Threads Termination .…………. 98
5.4 Assertion Refinement Process ….. 99
5.4.1 Relaxed, stringent assertion ….. 100
5.5 Unbounded Range $ in Properties ....………… 100
5.6 Recursion ..…………. 101
5.7 Emulating PSL-Like Constructs in SVA ...…………. 104
5.7.1 whilenot ……… 104
5.7.2 The eventually! Operator in Sequence …. 106
5.7.3 Emulating UNTIL with Sequences ....……. 106
5.7.4 F before G …….. 107
5.7.5 One-Shot Assertion Using Initial blocks ………. 108
5.7.5.1 Flag Bit Defining Start of Antecedent . 108
5.7.5.2 Procedural Assertion in Initial Block . 109
5.8 Assertion-Based System Functions ....…….. 109
5.8.1 Sampled Valued Functions ….. 109
5.8.1.1 Value access functions .. 109
5.8.1.1.1 $sampled(expression [, clocking_event]) …………… 110
5.8.1.1.2 $past ……… 111
5.8.1.2 Value change functions ………. 113
5.8.1.2.1 $rose and $fell ……… 113
5.8.1.2.2 $stable ……… 115
5.8.2 Vector-Analysis System Functions ...…… 116
5.8.3 Severity-level System Functions ...………… 116
5.8.4 Assertion-Control System Tasks ...………. 117
5.9 Clocked Sequence and Multi-Clocking ....……………. 118
5.9.1 Clock Specification for Properties and Sequences ...……. 118
5.9.2 Clock Resolution ..…….. 120
5.9.2.1 Clock Resolution in Assertion and Property Directives ....………. 121
5.9.2.2 Clock Resolution in Sequences .. 121
5.9.3 Multiple clocked sequences ...……. 123
5.9.3.1 Rules in Using Multiple-Clocked Sequence ...…... 125
5.9.4 Multiple-clocked properties ...……. 127
5.9.5 Clock flow ..……… 128
5.9.6 Clocking Rules in Assertions ..….. 129
5.9.6.1 Single clocked assertions: ...……… 130
5.9.6.2 Sequence and Properties in Clocking Blocks ....…. 130
5.9.6.3 Multiple-clocked Assertions ...…… 131
5.10 SystemVerilog Scheduling semantics for Assertions ....….. 131
5.11 Properties in Interfaces ...………. 134
5.12 Verification Directives ....…. 135
5.12.1 assert Directive .……….. 135
5.12.1.1 Concurrent Assertion Statements Outside of Procedural Code ....……. 135
5.12.1.2 Concurrent Assertion Statements Embedded in Procedural Block 136
5.12.1.3 Immediate assertion: . 137
5.12.1.4 Action-block . 137
5.12.2 assume Directive ..……. 138
5.12.3 cover Directive . 140
5.12.4 Expect Construct ..…… 142
5.13 Binding Properties to Scopes or Instances ....…… 143
5.14 Verifying VHDL Models with SystemVerilog Assertions ....……… 148
5.14.1 The Concept ..….. 148
5.14.2 VHDL Module in VHDL Testbench with SystemVerilog Assertions Module . 148
5.14.2.1 VHDL Model ... 149
5.14.2.2 SystemVerilog Assertions Module 149
5.14.2.3 Connecting SystemVerilog Assertions module to VHDL design ....…… 150
5.14.2.3.1 Direct Instantiation of SVA module into VHDL Testbench .... 150
5.14.2.3.2 Binding of SVA Verification Module to VHDL Model ....…… 151
5.14.3 VHDL Model in a SystemVerilog Testbench with SVA Module ....……….. 152
6 SystemVerilog Assertions In the Design Process … 153
6.1 Traditional Design Process ……….. 154
6.2 Design Process with ABV using SVA as vehicle ………… 154
6.2.1 System-level Assertions ...………... 155
6.2.2 Interface Assertions …. 161
6.2.3 Architectural Plan ……. 161
6.2.4 Verification Plan …….. 162
6.2.5 RTL Design ..……. 163
6.2.6 Write Testbench and Simulate . 164
6.2.7 Analyze the Simulation Results and Coverage 164
6.2.8 Formal Verification (FV) …… 169
6.3 Case Study - Synchronous FIFO ....……….. 170
6.3.1 Synchronous FIFO Requirements ....…… 170
6.3.2 Verification Plan …….. 182
6.3.3 RTL Design ..…... 191
6.3.4 Simulation ……. 193
6.3.5 Formal Verification ..……. 193
Exercises .. 195
7 FORMAL VERIFICATION USING ASSERTIONS .. 199
7.1 FV METHODOLOGY ………….. 200
7.1.1 Model Checking Expectations and Rules . ….. 203
7.2 Role of SystemVerilog Assertions in FV ………… 204
7.2.1 SystemVerilog Assertions in Formal Specifications …. 204
7.2.2 SystemVerilog Assertions Usage in FV vs. Dynamic ABV …… 205
7.2.2.1 Same Inputs in Antecedent and Consequent ..….. 205
7.3 CASE STUDY - FV OF A TRAFFIC LIGHT CONTROLLER …………. 206
7.3.1 Model … 206
7.3.2 Basic requirements .…… 209
7.3.3 SystemVerilog Assertions for Traffic Light Controller .……… 209
7.3.4 Verification .…. 213
7.3.5 Good Traffic Light Controller 215
7.4 FV COVERAGE METRICS .…….. 216
7.4.1 Proof Radius ... 216
7.4.2 Explored State-Based Coverage …….. 217
7.4.3 Flip-flop to Property Distance 217
7.4.4 Functional Coverage Points .…. 217
7.5 EMERGING APPLICATIONS OF SYSTEMVERILOG ASSERTIONS
WITH FORMAL METHODS 217
7.5.1 SystemVerilog Assertions Based Performance Evaluation of Digital Systems 217
7.5.2 Hybrid (dynamic and formal) Verification .…. 218
7.5.3 Directed Random Test Generation from SystemVerilog Assertions .… 219
7.5.4 Achieving hard-to-hit functional coverage goals using Formal Methods ……. 219
7.6 Temporal Debugging .……. 222
7.7 SIMULATION OR FORMAL VERIFICATION? ………. 224
7.7.1 Arguments for Simulation with ABV .. 224
7.7.2 Arguments for Formal Verification …. 225
7.7.3 Balance .……….. 225
7.7.4 Recommendations .……. 226
7.7.5 Validity of Formal Verification results .……….. 226
8 SystemVerilog Assertions Guidelines .…. 229
8.1 Typographic Guidelines .…………. 230
8.1.1 Naming Convention …. 230
8.1.1.1 File naming ……………. 230
8.1.1.2 Object Naming ………. 230
8.1.1.3 Naming of Assertion Constructs ……………. 231
8.1.2 Ending Statements …… 231
8.1.3 Constants for Modules and Interfaces ……. 232
8.2 Use Model Guidelines … 232
8.2.1 Where to Write Properties and Assertions … 232
8.2.2 Assertions for Accuracy ……………….……… 234
8.2.2.1 Abide by Good Verilog Coding Style Rules . 234
8.2.2.2 Avoid Nested System Functions ……………. 234
8.2.2.3 Beware of unsized additions in +1 versus +1'b1 ………… 235
8.2.2.4 Beware of Property Negation Operator ….. 237
8.2.2.5 Ensure "Write before Read" while using Local Assertion Variables ………….. 238
8.2.2.6 Be Aware of Overlapping Assertions ………. 238
8.2.2.7 Beware of Metalogical Values ……………. 239
8.2.2.8 Avoid Vacuous Properties …………………. 239
8.2.2.9 Avoid Contradictory Properties ……….…… 239
8.2.3 Use $sampled Function in Action Block to Display Values of Current Variables 240
8.2.4 Accessing Local Variables in Assertions ……… 240
8.2.5 Style ….… 240
8.2.5.1 Avoid Unbounded Ranges …………………… 240
8.2.5.2 Use of Default Clock … 241
8.2.5.3 Evaluate Assertion Relative to a Clock ……… 241
8.2.5.4 Handling Resets in Properties ……………… 241
8.2.5.5 Defining Time Unit and Time Format Specifications for Design ………………… 242
8.2.5.6 Direct or Implicit Declaration of Properties . 245
8.2.5.7 Use Formal Arguments only when Reuse is Intended …… 246
8.2.5.8 Use module ports or Registered Signals in Properties …… 246
8.2.5.9 Standardize Action Block Error Display …… 247
8.2.5.10 Use generate Construct for Assertions Conditional on Parameters ………… 247
8.2.5.11 Use Pattern Format in Documenting Assertions ……… 248
8.2.5.12 Review Properties and Assertions Against Requirements ……………………. 248
8.2.5.13 Simulate Design … 248
8.2.5.14 Guidelines for Debugging Assertions …. 249
8.2.6 Using SystemVerilog assertions with Verilog RTL …………. 249
8.2.7 Using Dynamic Data Types inside Properties 250
8.3 Methodology Guidelines …. 251
8.3.1 Identifying Properties from Design Specifications ……….… 251
8.3.2 Classification of properties ………………….. 251
8.3.2.1 Design Centric . ……… 251
8.3.2.1.1 Style in FSM properties …………………… 251
8.3.2.2 Assumption Centric ….. 253
8.3.2.3 Requirement / Verification Centric ………… 253
8.3.2.4 Environmental Properties …………………. 254
8.3.2.5 Coverage Properties … 255
8.3.3 Process of Writing Properties and Assertions ……………... 256
9 SystemVerilog Assertions Dictionary 261
9.1 If COND1, then COND2 . 262
9.2 If COND1, then at next COND2, COND3 ……… 262
9.3 If COND1, then after nth COND2, COND3 ……. 263
9.4 If COND1 and first COND2, then COND3 until COND4 …….. 264
9.5 If COND1 and first COND2, then sequence ……… 264
9.6 Between COND1 and COND2, Signal 1 asserted .. 265
9.7 If COND1 and then 1 occurrence of COND2 then sequence ….. 266
9.8 If COND1 then N Occurrences of COND2 before COND3. N is value of signal …… 266
9.9 If COND1 and within n cycles y occurrences of COND2, then COND3 ……………….. 268
9.10 If COND1, then COND2 until COND3 ……… 269
9.11 If Cond1 then Cond2 before Cond3 …………. 269
9.12 If COND1 is followed by COND2, and COND3 is not received within 64 cycles while
COND2 then Error (COND5). If COND3 is received within 64 cycles then COND4 ……. 269
9.13 For every write (COND1), data transfers must alternate between
odd and even entries …… 271
9.14 If COND1 then COND2 in N cycles unless COND3 ………… 271
9.15 Data Integrity in Memory. Data read from Memory should be same as
what was last written …. 273
9.16 Data Integrity in QUEUES. Interface Data Written must be properly
transferred to the Receiving Hardware ……….. 274
9.17 Never 2 consecutive Writes with same Address ……………. 276
9.18 Cache controller requirement: A cached address (COND1) will eventually
be retired (COND2) and after that, within 2 to 7 clocks the cache
copy shall be invalidated (COND3) ………….. 277
9.19 during cond1 Never COND3 after COND2. Cond2 may occur within
n cycles after Cond1 …. 278
9.20 If COND1, then next N cycles COND2. If new COND1 before end of COND2,
then COND2 extended for N cycles until no COND1 ………. 278
9.21 Never two CONDs within 2 cycles Apart ……. 280
9.22 Assume Reset low for initial N cycles ………… 281
9.23 If COND1 and N cycle later COND2, then COND3 until COND4, unless COND5 .. 282
9.24 If Sequence COND1 followed by N non-necessarily consecutive COND2,
then N consecutive COND3 until COND4 …… 283
9.25 If COND1, COND2 doesn't change for N clocks, unless COND1 goes high again 283
9.26 If a Sequence Starts but does not Complete, then State Register must be in
ERROR state …………. 284
9.27 COND1 and COND2 are Mutually Exclusive .. 286
9.28 If Address Error, then eventually good address …………… 287
9.29 Enabling a property after a trigger ………….. 288
6 Appendix A Answers to Exercises ……. 289
A.1 Answers to Chapter 4 Exercises …………………. 289
A.2 Answers to Chapter 6 Exercise …………………. 298
Appendix B: Definitions 305
APPENDIX C: QUICK REFERENCE GUIDE ……… 313
APPENDIX D: CLOCK RESOLUTION .. 317
APPENDIX E: SYSTEMVERILOG ASSERTIONS SYNTAX ………. 321
Index ………… 325
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