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	# Developer Guide

	## Tool Philosophy

	OpenROAD is a tool to build a chip from synthesizable RTL (Verilog) to
	completed physical layout (manufacturable, tapeout-clean GDSII).

	The unifying principle behind the design of OpenROAD is for all of the
	tools to reside in one tool, with one process, and one database. All
	tools in the flow should use Tcl commands exclusively to control them
	instead of external "configuration files". File-based communication
	between tools and forking processes is strongly discouraged. This
	architecture streamlines the construction of a flexible tool flow and
	minimizes the overhead of invoking each tool in the flow.

	## Tool File Organization

	Every tool follows the following file structure, grouping sources, tests
	and headers together.

	- `src/`
	This folder contains the source files for individual tools.

	\| `src` \| Purpose \|
	\|-----------------\|--------------\|
	\| `CMakeLists.txt` \| `add_subdirectory` for each tool\|
	\| `tool/src` \| sources and private headers \|
	\| `tool/src/CMakeLists.txt` \| tool specific CMake file \|
	\| `tool/include/tool` \| exported headers \|
	\| `tool/test` \| tool tests \|
	\| `tool/regression` \| tool unit tests\|

	- OpenROAD repository:
	This folder contains the top-level files for overall compilation. OpenROAD uses [swig](https://swig.org/) that acts as a wrapper for C/C++ programs to be callable in higher-level languages, such as Python and Tcl.

	\| `OpenROAD` \| Purpose \|
	\|-----------------\|--------------\|
	\| `CMakeLists.txt` \| top-level CMake file \|
	\| `src/Main.cc` \| main file \|
	\| `src/OpenROAD.cc` \| OpenROAD class functions \|
	\| `src/OpenROAD.i` \| top-level swig, includes, tool swig files \|
	\| `src/OpenROAD.tcl` \| basic read/write lef/def/db commands \|
	\| `include/ord/OpenROAD.hh` \| OpenROAD top-level class, has instances of tools \|

	Some tools such as OpenSTA are submodules, which are simply
	subdirectories in `src/` that are pointers to the git submodule. They are
	intentionally not segregated into a separate module.

	The use of submodules for new code integrated into OpenROAD is strongly
	discouraged. Submodules make changes to the underlying infrastructure
	(e.g., OpenSTA) difficult to propagate across the dependent submodule
	repositories.

	Where external/third-party code that a tool depends on should be placed
	depends on the nature of the dependency.

	- Libraries - code packaged as a linkable library. Examples are `tcl`,
	`boost`, `zlib`, `eigen`, `lemon`, `spdlog`.

	These should be installed in the build environment and linked by
	OpenROAD. Document these dependencies in the top-level `README.md` file.
	The `Dockerfile` should be updated to illustrate where to find the library
	and how to install it. Adding libraries to the build environment requires
	coordination with system administrators, so that continuous integration hosts ensure
	that environments include the dependency. Advance notification
	should also be given to the development team so that their private build
	environments can be updated.

	Each tool CMake file builds a library that is linked by the OpenROAD
	application. The tools should not define a `main()` function. If the
	tool is Tcl only and has no C++ code, it does not need to have a CMake
	file. Tool CMake files should not include the following:

	- `cmake_minimum_required`
	- `GCC_COVERAGE_COMPILE_FLAGS`
	- `GCC_COVERAGE_LINK_FLAGS`
	- `CMAKE_CXX_FLAGS`
	- `CMAKE_EXE_LINKER_FLAGS`

	None of the tools have commands to read or write LEF, DEF, Verilog or
	database files. For consistency, these functions are all provided by the OpenROAD
	framework.

	Tools should package all of their state in a single class. An instance of each
	tool class resides in the top-level OpenROAD object. This allows
	multiple tools to exist at the same time. If any tool keeps state in
	global variables (even static), then only one tool can exist at a time. Many
	of the tools being integrated were not built with this goal in mind and
	will only work on one design at a time.

	Each tool should use a unique namespace for all of its code. The same
	namespace should be used for Tcl functions, including those defined by a
	swig interface file. Internal Tcl commands stay inside the namespace,
	and user visible Tcl commands should be defined in the global namespace.
	User commands should be simple Tcl commands such as `global_placement`
	that do not create tool instances that must be based to the commands.
	Defining Tcl commands for a tool class is fine for internal commands, but not
	for user visible commands. Commands have an implicit argument of the
	current OpenROAD class object. Functions to get individual tools from
	the OpenROAD object can be defined.

	## Initialization (C++ tools only)

	The OpenROAD class has pointers to each tool, with functions to get each
	tool. Each tool has (at a minimum) a function to make an instance of the
	tool class, an initialization function that is called after all of
	the tools have been made, and a function to delete the tool. This small
	header does not include the class definition for the tool so that
	the OpenROAD framework does not have to know anything about the tool
	internals or include a gigantic header file.

	`MakeTool.hh` defines the following:

	``` cpp
	Tool *makeTool();
	void initTool(OpenRoad *openroad);
	void deleteTool(Tool *tool);
	```

	The `OpenRoad::init()` function calls all of the `makeTool` functions and
	then all of the `initTool()` functions. The `init` functions are called from
	the bottom of the tool dependencies. Each `init` function grabs the state
	it needs out of the `OpenRoad` instance.

	## Commands

	Tools should provide Tcl commands to control them. Tcl object based tool
	interfaces are not user-friendly. Define Tcl procedures that take
	keyword arguments that reference the `OpenRoad` object to get tool state.
	OpenSTA has Tcl utilities to parse keyword arguments
	(`sta::parse_keyword_args`). See `OpenSTA/tcl/*.tcl` for
	examples. Use swig to define internal functions to C++ functionality.

	Tcl files can be included by encoding them in CMake into a string that
	is evaluated at run time (See [`Resizer::init()`](../main/src/rsz/src/Resizer.cc)).

	:::{Note}
	Please refer to the top-level Tcl formatting [guide](TclFormat.md).
	Our top-level Tcl files, in particular, have to be formatted in this specific
	manner because of the automatic parsing used to convert the READMEs into
	manpages.
	:::

	## Errors

	Tools should report errors to the user using the `ord::error` function
	defined in `include/openroad/Error.hh`. `ord::error` throws
	`ord::Exception`. The variables `ord::exit_on_error` and
	`ord::file_continue_on_error` control how the error is handled. If
	`ord::exit_on_error` is `true` then OpenROAD reports the error and exits. If
	the error is encountered while reading a file with the `source` or
	`read_sdc` commands and `ord::file_continue_on_error` is `false` then no
	other commands are read from the file. The default value is `false` for both
	variables.

	## Test

	Each "tool" has a `/test` directory containing a script named
	`regression` to run "unit" tests. With no arguments it should run
	default unit tests.

	No database files should be in tests. Read LEF/DEF/Verilog to make a
	database.

	The regression script should not depend on the current working
	directory. It should be able to be run from any directory. Use filenames
	relative to the script name rather the current working directory.

	Regression scripts should print a concise summary of test failures. The
	regression script should return an exit code of 0 if there are no
	errors and 1 if there are errors. The script should not print
	thousands of lines of internal tool information.

	Regression scripts should pass the `-no_init` option to `openroad` so that
	a user's `init` file is not sourced before the tests runs.

	Regression scripts should add output files or directories to
	`.gitignore` so that running does not leave the source repository
	"dirty".

	The Nangate45 open-source library data used by many tests is in
	`test/Nangate45`. Use the following command to add a link in the tool command:

	``` shell
	cd src/<tool>/test
	ln -s ../../../test/Nangate45
	```

	After the link is installed, the test script can read the Liberty file
	with the command shown below.

	``` tcl
	read_liberty Nangate45/Nangate45_typ.lib
	```

	## Building

	Instructions for building are available [here](../user/Build.md).

	## Example of Adding a Tool to OpenROAD

	The patch file "AddTool.patch" illustrates how to add a tool to
	OpenROAD. Use the following commands to add a sample tool:

	``` shell
	# first, update existing config files
	patch -p1 < docs/misc/AddTool.patch

	# next, create the additional source files of the tool using this command
	patch -p1 < docs/misc/AddToolFiles.patch

	# finally, create the regression tests as follows
	cd src/tool/test
	ln -s ../../../test/regression.tcl regression.tcl
	```

	This adds a directory `OpenRoad/src/tool` that
	illustrates a tool named "Tool" that uses the file structure described above
	and defines a command to run the tool with keyword and flag arguments as
	illustrated below:

	```tcl
	> toolize foo
	Helping 23/6
	Gotta positional_argument1 foo
	Gotta param1 0.000000
	Gotta flag1 false

	> toolize -flag1 -key1 2.0 bar
	Helping 23/6
	Gotta positional_argument2 bar
	Gotta param1 2.000000
	Gotta flag1 true

	> help toolize
	toolize [-key1 key1] [-flag1] positional_argument1
	```

	## Documentation

	Tool commands should be documented in the top-level OpenROAD `README.md`
	file. Detailed documentation should be the `tool/README.md` file.

	:::{Note}
	Please refer to the README formatting [guide](ReadmeFormat.md).
	Our top-level READMEs, in particular, have to be formatted in this specific
	manner because of the automatic parsing used to convert the READMEs into
	manpages.
	:::

	## Tool Flow Namespace

	Tool namespaces are usually three-lettered lowercase letters.

	- Verilog to DB (dbSTA)
	- OpenDB: Open Database ([odb](../main/src/odb/README.md))
	- TritonPart: constraints-driven paritioner ([par](../main/src/par/README.md))
	- Floorplan Initialization ([ifp](../main/src/ifp/README.md))
	- ICeWall chip-level connections ([pad](../main/src/pad/README.md))
	- I/O Placement ([ppl](../main/src/ppl/README.md))
	- PDN Generation ([pdn](../main/src/pdn/README.md))
	- Tapcell and Welltie Insertion ([tap](../main/src/tap/README.md))
	- Triton Macro Placer ([mpl](../main/src/mpl/README.md))
	- Hierarchical Automatic Macro Placer ([mpl2](../main/src/mpl2/README.md))
	- RePlAce Global Placer ([gpl](../main/src/gpl/README.md))
	- Gate resizing and buffering ([rsz](../main/src/rsz/README.md))
	- Detailed placement ([dpl](../main/src/dpl/README.md))
	- Clock tree synthesis ([cts](../main/src/cts/README.md))
	- FastRoute Global routing ([grt](../main/src/grt/README.md))
	- Antenna check and diode insertion ([ant](../main/src/ant/README.md))
	- TritonRoute Detailed routing ([drt](../main/src/drt/README.md))
	- Metal fill insertion ([fin](../main/src/fin/README.md))
	- Design for Test ([dft](../main/src/dft/README.md))
	- OpenRCX Parasitic Extraction ([rcx](../main/src/rcx/README.md))
	- OpenSTA timing/power analyzer ([sta](https://github.com/The-OpenROAD-Project/OpenSTA/blob/master/README.md)
	- Graphical User Interface ([gui](../main/src/gui/README.md))
	- Static IR analyzer ([psm](../main/src/psm/README.md))

	## Tool Checklist

	Tools should make every attempt to minimize external dependencies.
	Linking libraries other than those currently in use complicates the
	builds and sacrifices the portability of OpenROAD. OpenROAD should be
	portable to many different compiler/operating system versions and
	dependencies make this vastly more complicated.

	1. OpenROAD submodules reference tool `openroad` branch head. No git `develop`, `openroad_app`, or `openroad_build` branches.
	1. Submodules used by more than one tool belong in `src/`, not duplicated in each tool repo.
	1. `CMakeLists.txt` does not use add_compile_options include_directories link_directories link_libraries. Use target\_ versions instead. See tips [here](https://gist.github.com/mbinna/c61dbb39bca0e4fb7d1f73b0d66a4fd1).
	1. `CMakeLists.txt` does not use glob. Use explicit lists of source files and headers instead.
	1. `CMakeLists.txt` does not define `CFLAGS` `CMAKE_CXX_FLAGS` `CMAKE_CXX_FLAGS_DEBUG` `CMAKE_CXX_FLAGS_RELEASE`. Let the top level and defaults control these.
	1. No `main.cpp` or main procedure.
	1. No compiler warnings for GCC or Clang with optimization enabled.
	1. Does not call `flute::readLUT` (called once by `openroad`).
	1. Tcl command(s) documented in top level `README.md` in flow order.
	1. Command line tool documentation in tool README.
	1. Conforms to Tcl command naming standards (no camel case).
	1. Does not read configuration files. Use command arguments or support commands.
	1. `.clang-format` at tool root directory to aid foreign programmers.
	1. No `jenkins/`, `Jenkinsfile`, `Dockerfile` in tool directory.
	1. `regression` script named `test/regression` with no arguments that runs tests. Not `tests/regression-tcl.sh`, not `test/run_tests.py` etc.
	1. `regression` script should run independent of current directory. For example, `../test/regression` should work.
	1. `regression` should only print test results or summary, not belch 1000s of lines of output.
	1. Test scripts use OpenROAD tcl commands (not `itcl`, not internal accessors).
	1. `regression` script should only write files in a directory that is in the tool's `.gitignore` so the hierarchy does not have modified files in it as a result or running the regressions.
	1. Regressions report no memory errors with `valgrind` (stretch goal).
	1. Regressions report no memory leaks with `valgrind` (difficult).
	1. Ensure the top-level README and Tcl format are compliant.

	## Code Linting and Formatting
	OpenROAD uses both `clang-tidy` and `clang-format` to perform automatic linting and formatting whenever a pull request is submitted. To run these locally, please first setup Clang Tooling using this [guide](https://clang.llvm.org/docs/HowToSetupToolingForLLVM.html). Thereafter, you may run these commands:

	```shell
	cmake . -B build # generate build files
	# typically only run these commands on files you changed.
	clang-tidy -p ./build source_file.cpp
	clang-format -i -style=file:.clang-format source_file.cpp
	```

	## Guidelines

	1. Internally, the code should use `int` for all database units and `int64_t`
	for all area calculations. Refer to this [link](DatabaseMath.md) for a more
	detailed writeup on the reasons why this approach is preferred. The only
	place that the database distance units should appear in any program
	should be in the user interface, as microns are easier for humans than DBUs.