Using the CLOCK_LOW_FANOUT Constraint - 2021.2 English

UltraFast Design Methodology Guide for Xilinx FPGAs and SoCs

Document ID
UG949
Release Date
2021-11-19
Version
2021.2 English

You can use the CLOCK_LOW_FANOUT constraint to contain the loads of a clock buffer in a single clock region. You can set the CLOCK_LOW_FANOUT constraint on a clock net segment directly driven by a global clock buffer or on a list of flip-flops.

Note: The CLOCK_LOW_FANOUT constraint takes lower precedence when used with other clocking constraints. If CLOCK_LOW_FANOUT is in conflict with other clock constraints, such as USER_CLOCK_ROOT, CLOCK_DELAY_GROUP, or CLOCK_DEDICATED_ROUTE, CLOCK_LOW_FANOUT is not obeyed.

Constraint Example for Flip-Flops

Setting the CLOCK_LOW_FANOUT constraint on a list of flip-flops driven by a global clock buffer causes opt_design to create a new parallel global clock buffer to isolate the flip-flops. During place_design, the isolated flip-flops that are driven by the newly created parallel global clock buffer are contained to a single clock region.

The following example shows the CLOCK_LOW_FANOUT constraint applied to a list of flip-flops that are used as part of a clock gating synchronization circuit to control the clock enable of a global clock buffer.
set_property CLOCK_LOW_FANOUT TRUE [get_cells safeClockStartup_reg[*]]

In the design, an always-on clock network initially drives more than 2000 loads, including the flip-flops that are part of the clock gating synchronization circuit used to clock gate other logic. The following schematics show the clock gating synchronization circuit and additional logic connected to the always-on clock network before and after opt_design creates a new parallel global clock buffer to isolate the clock gating synchronization circuit.

Figure 1. Schematic Before opt_design Transform with CLOCK_LOW_FANOUT Applied to Flip-Flops
Figure 2. Schematic After opt_design Transform with CLOCK_LOW_FANOUT Applied to Flip-Flops

The Device window of the fully implemented design shows the clock gating synchronization circuit with green markers along with the always-on logic and clock-gated logic. The clock gating synchronization circuit is placed in the same CLOCK_REGION as the MMCM, close to the global clock buffers.

Figure 3. Fully Implemented Design with Placement of Clock Gating Synchronization Circuit

Constraint Example for Clock Nets

If you set the CLOCK_LOW_FANOUT property on a clock net segment directly driven by a global clock buffer and the fanout of the global clock buffer is less than 2000 loads, the placement of the loads is contained to a single clock region.

The following example shows the CLOCK_LOW_FANOUT constraint applied to the clock net segment directly driven by a global clock buffer. The clock network drives less than 2000 loads and is contained to a single clock region. The input clock port, clkIn has a PACKAGE_PIN assignment to a GCIO located in the CLOCK_REGION X2Y0 and drives a PLLE3_ADV. The PLLE3_ADV drives a global clock buffer that subsequently drives the clock network with 1379 loads. The loads of the global clock buffer are all placed in the CLOCK_REGION X2Y0.

# PACKAGE_PIN AF9 - IOBank 64 - CLOCK_REGION X2Y0
set_property PACKAGE_PIN AF9 [get_ports clkIn]
set_property IOSTANDARD LVCMOS18 [get_ports clkIn]
set_property CLOCK_LOW_FANOUT TRUE [get_nets -of [get_pins clkOut0_bufg_inst/O]]
Figure 4. CLOCK_LOW_FANOUT Example in the Device Window and Schematic Window