The global routing module in OpenROAD (grt
) is based on FastRoute, an
open-source global router originally derived from Iowa State University's
FastRoute4.1 algorithm.
- Parameters in square brackets `[-param param]` are optional.
- Parameters without square brackets `-param2 param2` are required.
This command performs global routing with the option to use a guide_file
.
You may also choose to use incremental global routing using -start_incremental
.
global_route
[-guide_file out_file]
[-congestion_iterations iterations]
[-congestion_report_file file_name]
[-congestion_report_iter_step steps]
[-grid_origin {x y}]
[-critical_nets_percentage percent]
[-allow_congestion]
[-allow_overflow]
[-overflow_iterations]
[-verbose]
[-start_incremental]
[-end_incremental]
Switch Name | Description |
---|---|
-guide_file |
Set the output guides file name (e.g., route.guide ). |
-congestion_iterations |
Set the number of iterations made to remove the overflow of the routing. The default value is 50 , and the allowed values are integers [0, MAX_INT] . |
-congestion_report_file |
Set the file name to save the congestion report. The file generated can be read by the DRC viewer in the GUI (e.g., report_file.rpt ). |
-congestion_report_iter_step |
Set the number of iterations to report. The default value is 0 , and the allowed values are integers [0, MAX_INT] . |
-grid_origin |
Set the (x, y) origin of the routing grid in DBU. For example, -grid_origin {1 1} corresponds to the die (0, 0) + 1 DBU in each x--, y- direction. |
-critical_nets_percentage |
Set the percentage of nets with the worst slack value that are considered timing critical, having preference over other nets during congestion iterations (e.g. -critical_nets_percentage 30 ). The default value is 0 , and the allowed values are integers [0, MAX_INT] . |
-allow_congestion |
Allow global routing results to be generated with remaining congestion. The default is false. |
-verbose |
This flag enables the full reporting of the global routing. |
-start_incremental |
This flag initializes the GRT listener to get the net modified. The default is false. |
-end_incremental |
This flag run incremental GRT with the nets modified. The default is false. |
This command sets the minimum and maximum routing layers for signal and clock nets.
Example: set_routing_layers -signal Metal2-Metal10 -clock Metal6-Metal9
set_routing_layers
[-signal min-max]
[-clock min-max]
Switch Name | Description |
---|---|
-signal |
Set the min and max routing signal layer (names) in this format "%s-%s". |
-clock |
Set the min and max routing clock layer (names) in this format "%s-%s". |
This command sets the halo (in terms of GCells) along the boundaries of macros.
A GCell
is typically defined in terms of Mx
routing tracks.
Example: set_macro_extension 2
set_macro_extension extension
Argument Name | Description |
---|---|
extension |
Number of GCells added to the blockage boundaries from macros. The default GCell size is 15 M3 pitches. |
This command sets the pin offset distance.
set_pin_offset offset
Argument Name | Description |
---|---|
offset |
Pin offset in microns (must be a positive integer). |
The set_global_routing_layer_adjustment
command sets routing resource
adjustments in the routing layers of the design. Such adjustments reduce the number of
routing tracks that the global router assumes to exist. This promotes the spreading of routing
and reduces peak congestion, to reduce challenges for detailed routing.
You can set adjustment for a
specific layer, e.g., set_global_routing_layer_adjustment Metal4 0.5
reduces
the routing resources of routing layer Metal4
by 50%. You can also set adjustment
for all layers at once using *
, e.g., set_global_routing_layer_adjustment * 0.3
reduces the routing resources of all routing layers by 30%. And, you can
also set resource adjustment for a layer range, e.g.: set_global_routing_layer_adjustment Metal4-Metal8 0.3
reduces the routing resources of routing layers Metal4
,
Metal5
, Metal6
, Metal7
and Metal8
by 30%.
set_global_routing_layer_adjustment layer adjustment
Argument Name | Description |
---|---|
layer |
Integer for the layer number (e.g. for M1 you would use 1). |
adjustment |
Float indicating the percentage reduction of each edge in the specified layer. |
Set global routing region adjustment.
Example: set_global_routing_region_adjustment {1.5 2 20 30.5} -layer Metal4 -adjustment 0.7
set_global_routing_region_adjustment
{lower_left_x lower_left_y upper_right_x upper_right_y}
-layer layer
-adjustment adjustment
Switch Name | Description |
---|---|
lower_left_x , lower_left_y , upper_right_x , upper_right_y |
Bounding box to consider. |
-layer |
Integer for the layer number (e.g. for M1 you would use 1). |
-adjustment |
Float indicating the percentage reduction of each edge in the specified layer. |
The command randomizes global routing by shuffling the order of the nets and randomly subtracts or adds to the capacities of a random set of edges.
Example:
set_global_routing_random -seed 42 \ -capacities_perturbation_percentage 50 \ -perturbation_amount 2
set_global_routing_random
[-seed seed]
[-capacities_perturbation_percentage percent]
[-perturbation_amount value]
Switch Name | Description |
---|---|
-seed |
Sets the random seed (must be non-zero for randomization). |
-capacities_perturbation_percentage |
Sets the percentage of edges whose capacities are perturbed. By default, the edge capacities are perturbed by adding or subtracting 1 (track) from the original capacity. |
-perturbation_amount |
Sets the perturbation value of the edge capacities. This option is only meaningful when -capacities_perturbation_percentage is used. |
The set_nets_to_route
command defines a list of nets to route. Only the nets
defined in this command are routed, leaving the remaining nets without any
global route guides.
set_nets_to_route
net_names
Switch Name | Description |
---|---|
net_names |
Tcl list of set of nets (e.g. {net1, net2} ). |
The repair_antennas
command checks the global routing for antenna
violations and repairs the violations by inserting diodes near the
gates of the violating nets. By default the command runs only one
iteration to repair antennas. Filler instances added by the
filler_placement
command should NOT be in the database when
repair_antennas
is called.
See LEF/DEF 5.8 Language Reference, Appendix C, "Calculating and Fixing Process Antenna Violations" for a description of antenna violations.
If no diode_cell
argument is specified the LEF cell with class CORE, ANTENNACELL will be used.
If any repairs are made the filler instances are remove and must be
placed with the filler_placement
command.
If the LEF technology layer ANTENNADIFFSIDEAREARATIO
properties are constant
instead of PWL, inserting diodes will not improve the antenna ratios,
and thus, no
diodes are inserted. The following warning message will be reported:
[WARNING GRT-0243] Unable to repair antennas on net with diodes.
repair_antennas
[diode_cell]
[-iterations iterations]
[-ratio_margin margin]
Switch Name | Description |
---|---|
diode_cell |
Diode cell to fix antenna violations. |
-iterations |
Number of iterations. The default value is 1 , and the allowed values are integers [0, MAX_INT] . |
-ratio_margin |
Add a margin to the antenna ratios. The default value is 0 , and the allowed values are integers [0, 100] . |
The draw_route_guides
command plots the route guides for a set of nets.
To erase the route guides from the GUI, pass an empty list to this command:
draw_route_guides {}
.
draw_route_guides
net_names
[-show_pin_locations]
Switch Name | Description |
---|---|
net_names |
Tcl list of set of nets (e.g. {net1, net2} ). |
-show_pin_locations |
Draw circles for the pin positions on the routing grid. |
The report_wire_length
command reports the wire length of the nets. Use the -global_route
and the -detailed_route
flags to report the wire length from global and detailed routing,
respectively. If none of these flags are used, the tool will identify the state of the design
and report the wire length accordingly.
Example: report_wire_length -net {clk net60} -global_route -detailed_route -verbose -file out.csv
report_wire_length
[-net net_list]
[-file file]
[-global_route]
[-detailed_route]
[-verbose]
Switch Name | Description |
---|---|
-net |
List of nets to report the wirelength. Use * to report the wire length for all nets of the design. |
-file |
The name of the file for the wirelength report. |
-global_route |
Report the wire length of the global routing. |
-detailed_route |
Report the wire length of the detailed routing. |
-verbose |
This flag enables the full reporting of the layer-wise wirelength information. |
The global_route_debug
command allows you to start a debug mode to view the status of the Steiner Trees.
It also allows you to dump the input positions for the Steiner tree creation of a net.
This must be used before calling the global_route
command.
Set the name of the net and the trees that you want to visualize.
global_route_debug
[-st]
[-rst]
[-tree2D]
[-tree3D]
[-saveSttInput file_name]
[-net net_name]
Switch Name | Description |
---|---|
-st |
Show the Steiner Tree generated by stt . |
-rst |
Show the Rectilinear Steiner Tree generated by grt . |
-tree2D |
Show the Rectilinear Steiner Tree generated by grt after the overflow iterations. |
-tree3D |
Show the 3D Rectilinear Steiner Tree post-layer assignment. |
-saveSttInput |
File name to save stt input of a net. |
-net |
The name of the net name to be displayed. |
This command reads global routing guides.
read_guides file_name
Switch Name | Description |
---|---|
file_name |
Path to global routing guide. |
Examples scripts demonstrating how to run FastRoute on a sample design of gcd
as follows:
./test/gcd.tcl
If you are a developer, you might find these useful. More details can be found in the source file or the swig file.
Command Name | Description |
---|---|
check_routing_layer |
Check if the layer is within the min/max routing layer specified. |
parse_layer_name |
Get routing layer number from layer name |
parse_layer_range |
Parses a range from layer_range argument of format (%s-%s). cmd argument is not used. |
check_region |
Checks the defined region if its within the die area. |
define_layer_range |
Provide a Tcl list of layers and automatically generate the min and max layers for signal routing. |
define_clock_layer_range |
Provide a Tcl list of layers and automatically generate the min and max layers for clock routing. |
have_detailed_route |
Checks if block has detailed route already. |
There are a set of regression tests in ./test
. For more information, refer to this section.
Simply run the following script:
./test/regression
The `Python` interface is currently in development and is subject to change.
The Python
API tries to stay close to the API defined in the C++
class
GlobalRouter
that is located here
When initializing a design, a sequence of Python
commands might look like
the following:
from openroad import Design, Tech
tech = Tech()
tech.readLef(...)
design = Design(tech)
design.readDef(...)
gr = design.getGlobalRouter()
Here are some options to the global_route
command. (See GlobalRouter.h
for a complete list)
gr.setGridOrigin(x, y) # int, default 0,0
gr.setCongestionReportFile(file_name) # string
gr.setOverflowIterations(n) # int, default 50
gr.setAllowCongestion(allowCongestion) # boolean, default False
gr.setCriticalNetsPercentage(percentage) # float
gr.setMinRoutingLayer(minLayer) # int
gr.setMaxRoutingLayer(maxLayer) # int
gr.setMinLayerForClock(minLayer) # int
gr.setMaxLayerForClock(maxLayer) # int
gr.setVerbose(v) # boolean, default False
and when ready to actually do the global route:
gr.globalRoute(save_guides) # boolean, default False
If you have set save_guides
to True, you can then save the guides in file_name
with:
design.getBlock().writeGuides(file_name)
You can find the index of a named layer with
lindex = tech.getDB().getTech().findLayer(layer_name)
or, if you only have the Python
design object
lindex = design.getTech().getDB().getTech().findLayer(layer_name)
Be aware that much of the error checking is done in Tcl
, so that with
the current C++
/ Python
API, that might be an issue to deal
with. There are also some useful Python
functions located in the grt_aux.py
file
but these are not considered a part of the final API and may be subject to change.
Check out GitHub discussion about this tool.
- Database comes from OpenDB
- FastRoute 4.1 documentation. The FastRoute4.1 version was received from Yue Xu on June 15, 2019.
- Min Pan, Yue Xu, Yanheng Zhang and Chris Chu. "FastRoute: An Efficient and High-Quality Global Router. VLSI Design, Article ID 608362, 2012." Available here.
- C. J. Alpert, T. C. Hu, J. H. Huang, A. B. Kahng and D. Karger, "Prim-Dijkstra Tradeoffs for Improved Performance-Driven Global Routing", IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems 14(7) (1995), pp. 890-896. Available here.
BSD 3-Clause License. See LICENSE file.