Visible to Intel only — GUID: mtr1430269571886
Ixiasoft
1. Intel® Hyperflex™ FPGA Architecture Introduction
2. Intel® Hyperflex™ Architecture RTL Design Guidelines
3. Compiling Intel® Hyperflex™ Architecture Designs
4. Design Example Walk-Through
5. Retiming Restrictions and Workarounds
6. Optimization Example
7. Intel® Hyperflex™ Architecture Porting Guidelines
8. Appendices
9. Intel® Hyperflex™ Architecture High-Performance Design Handbook Archive
10. Intel® Hyperflex™ Architecture High-Performance Design Handbook Revision History
2.4.2.1. High-Speed Clock Domains
2.4.2.2. Restructuring Loops
2.4.2.3. Control Signal Backpressure
2.4.2.4. Flow Control with FIFO Status Signals
2.4.2.5. Flow Control with Skid Buffers
2.4.2.6. Read-Modify-Write Memory
2.4.2.7. Counters and Accumulators
2.4.2.8. State Machines
2.4.2.9. Memory
2.4.2.10. DSP Blocks
2.4.2.11. General Logic
2.4.2.12. Modulus and Division
2.4.2.13. Resets
2.4.2.14. Hardware Re-use
2.4.2.15. Algorithmic Requirements
2.4.2.16. FIFOs
2.4.2.17. Ternary Adders
5.2.1. Insufficient Registers
5.2.2. Short Path/Long Path
5.2.3. Fast Forward Limit
5.2.4. Loops
5.2.5. One Critical Chain per Clock Domain
5.2.6. Critical Chains in Related Clock Groups
5.2.7. Complex Critical Chains
5.2.8. Extend to locatable node
5.2.9. Domain Boundary Entry and Domain Boundary Exit
5.2.10. Critical Chains with Dual Clock Memories
5.2.11. Critical Chain Bits and Buses
5.2.12. Delay Lines
Visible to Intel only — GUID: mtr1430269571886
Ixiasoft
2.2.1.2. Synchronous Resets on Global Clock Trees
Using a global clock tree to distribute a synchronous reset may limit retiming performance improvements by the Compiler. Global clock trees do not have Hyper-Registers. As such, there is less flexibility to retime registers that fan-out through a global clock tree compared with fan-out to the routing fabric.