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FPGA Optimization Guide for Intel® oneAPI Toolkits
Introduction To FPGA Design Concepts
Analyze Your Design
Optimize Your Design
FPGA Optimization Flags, Attributes, Pragmas, and Extensions
Quick Reference
Additional Information
Document Revision History for the FPGA Optimization Guide for Intel® oneAPI Toolkits
Refactor the Loop-Carried Data Dependency
Relax Loop-Carried Dependency
Transfer Loop-Carried Dependency to Local Memory
Minimize the Memory Dependencies for Loop Pipelining
Unroll Loops
Fuse Loops to Reduce Overhead and Improve Performance
Optimize Loops With Loop Speculation
Remove Loop Bottlenecks
Shannonization to Improve FMAX/II
Optimize Inner Loop Throughput
Improve Loop Performance by Caching On-Chip Memory
Global Memory Bandwidth Use Calculation
Manual Partition of Global Memory
Partitioning Buffers Across Different Memory Types (Heterogeneous Memory)
Partitioning Buffers Across Memory Channels of the Same Memory Type
Ignoring Dependencies Between Accessor Arguments
Contiguous Memory Accesses
Static Memory Coalescing
Specify Schedule FMAX Target for Kernels (-Xsclock=<clock target>)
Disable Burst-Interleaving of Global Memory (-Xsno-interleaving=<global_memory_type>)
Force Ring Interconnect for Global Memory (-Xsglobal-ring)
Force a Single Store Ring to Reduce Area (-Xsforce-single-store-ring)
Force Fewer Read Data Reorder Units to Reduce Area (-Xsnum-reorder)
Disable Hardware Kernel Invocation Queue (-Xsno-hardware-kernel-invocation-queue)
Modify the Handshaking Protocol Between Clusters (-Xshyper-optimized-handshaking)
Disable Automatic Fusion of Loops (-Xsdisable-auto-loop-fusion)
Fuse Adjacent Loops With Unequal Trip Counts (-Xsenable-unequal-tc-fusion)
Pipeline Loops in Non-task Kernels (-Xsauto-pipeline)
Control Semantics of Floating-Point Operations (-fp-model=<value>)
Modify the Rounding Mode of Floating-point Operations (-Xsrounding=<rounding_type>)
Global Control of Exit FIFO Latency of Stall-free Clusters (-Xssfc-exit-fifo-type=<value>)
Enable the Read-Only Cache for Read-Only Accessors (-Xsread-only-cache-size=<N>)
Control Hardware Implementation of the Supported Data Types and Math Operations (-Xsdsp-mode=<option>)
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Limitations
The Intel® FPGA Dynamic Profiler for DPC++ has some limitations:
- Profile data is not persistent across SYCL* programs or multiple devices.
- The Profiler is unique to each SYCL program and device, meaning, each program on each device has its own profiler information. If your host swaps a new kernel program in and out of the FPGA, the Profiler does not save any data.
- Profile data is not saved on a device for later profiling.
- All profiling data is read to the host during execution and is only stored on the device long enough to be read on the next readback. Any reprogramming of new designs or restarting the same design results in new profiling data, erasing any previous data that may have existed.
- Instrumenting the design with performance counters increases hardware resource utilization (that is, FPGA area use) and typically decreases performance.
Parent topic: Intel® FPGA Dynamic Profiler for DPC++