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2.2.1. Timing Path and Clock Analysis
2.2.2. Clock Setup Analysis
2.2.3. Clock Hold Analysis
2.2.4. Recovery and Removal Analysis
2.2.5. Multicycle Path Analysis
2.2.6. Metastability Analysis
2.2.7. Timing Pessimism
2.2.8. Clock-As-Data Analysis
2.2.9. Multicorner Timing Analysis
2.2.10. Time Borrowing
3.1. Timing Analysis Flow
3.2. Step 1: Specify Timing Analyzer Settings
3.3. Step 2: Specify Timing Constraints
3.4. Step 3: Run the Timing Analyzer
3.5. Step 4: Analyze Timing Reports
3.6. Applying Timing Constraints
3.7. Timing Analyzer Tcl Commands
3.8. Timing Analysis of Imported Compilation Results
3.9. Using the Intel® Quartus® Prime Timing Analyzer Document Revision History
3.10. Intel® Quartus® Prime Pro Edition User Guide: Timing Analyzer Archive
3.5.1.1. Report Fmax Summary
3.5.1.2. Report Timing
3.5.1.3. Report Timing By Source Files
3.5.1.4. Report Data Delay
3.5.1.5. Report Net Delay
3.5.1.6. Report Clocks and Clock Network
3.5.1.7. Report Clock Transfers
3.5.1.8. Report Metastability
3.5.1.9. Report CDC Viewer
3.5.1.10. Report Asynchronous CDC
3.5.1.11. Report Logic Depth
3.5.1.12. Report Neighbor Paths
3.5.1.13. Report Register Spread
3.5.1.14. Report Route Net of Interest
3.5.1.15. Report Retiming Restrictions
3.5.1.16. Report Register Statistics
3.5.1.17. Report Pipelining Information
3.5.1.18. Report Time Borrowing Data
3.5.1.19. Report Exceptions and Exceptions Reachability
3.5.1.20. Report Bottlenecks
3.6.1. Recommended Initial SDC Constraints
3.6.2. SDC File Precedence
3.6.3. Modifying Iterative Constraints
3.6.4. Using Entity-bound SDC Files
3.6.5. Creating Clocks and Clock Constraints
3.6.6. Creating I/O Constraints
3.6.7. Creating Delay and Skew Constraints
3.6.8. Creating Timing Exceptions
3.6.9. Using Fitter Overconstraints
3.6.10. Example Circuit and SDC File
3.6.8.5.1. Default Multicycle Analysis
3.6.8.5.2. End Multicycle Setup = 2 and End Multicycle Hold = 0
3.6.8.5.3. End Multicycle Setup = 2 and End Multicycle Hold = 1
3.6.8.5.4. Same Frequency Clocks with Destination Clock Offset
3.6.8.5.5. Destination Clock Frequency is a Multiple of the Source Clock Frequency
3.6.8.5.6. Destination Clock Frequency is a Multiple of the Source Clock Frequency with an Offset
3.6.8.5.7. Source Clock Frequency is a Multiple of the Destination Clock Frequency
3.6.8.5.8. Source Clock Frequency is a Multiple of the Destination Clock Frequency with an Offset
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3.6.5.3.2. Clock Multiplexer Example
The output of a clock multiplexer (mux) is a form of generated clock. Each input clock requires one generated clock on the output. The following .sdc example also includes the set_clock_groups command to indicate that the two generated clocks can never be active simultaneously in the design. Therefore, the Timing Analyzer does not analyze cross-domain paths between the generated clocks on the output of the clock mux.
Figure 101. Clock Mux
create_clock -name clock_a -period 10 [get_ports clk_a] create_clock -name clock_b -period 10 [get_ports clk_b] create_generated_clock -name clock_a_mux -source [get_ports clk_a] \ [get_pins clk_mux|mux_out] create_generated_clock -name clock_b_mux -source [get_ports clk_b] \ [get_pins clk_mux|mux_out] -add set_clock_groups -logically_exclusive -group clock_a_mux -group clock_b_mux