binary_search_tool/MAINTENANCE - chromiumos/third_party/toolchain-utils - Git at Google

 # Copyright 2020 The Chromium OS Authors. All rights reserved.
 # Use of this source code is governed by a BSD-style license that can be
 # found in the LICENSE file.

 This document is for future maintainers of the binary search/bisection tools.

 Authors:
   * Original Tool: asharif@, llozano@, cmtice@
   * Updates after May 2016: cburden@
   * chromeos-toolchain@

 The following are good reference materials on how the tool works:
   * Ahmad's original presentation:
     https://goto.google.com/zxdfyi

   * Bisection tool update design doc:
     https://goto.google.com/zcwei

   * Bisection tool webpage:
     https://goto.google.com/ruwpyi

   * Compiler wrapper webpage:
     https://goto.google.com/xossn


 TESTING:
 All unit tests live under the ./test directory. However, these tests
 specifically test binary_search_state.py, binary_search_perforce.py,
 run_bisect.py.

 These unit tests will not test the specific logic for ChromeOS/Android
 bisection. To test the ChromeOS/Android bisectors, use the common/hash_test.sh
 test. This is a simple test case that just checks the hashes of files on your
 file system. This means you won't have to find a specific compiler error for
 the bisector to triage in order to test each bisector.

 TODO:
 The bisection tool (I believe) is in a fairly good state. So these are mostly
 wishlist items and things that could use some improvement.

   1. Get rid of binary_search_perforce.py. This file is mostly legacy code and
      the majority of it isn't even used to bisect object files. The file was
      originally intended to bisect CLs, and binary_search_state.py just reused
      the binary searching logic from it. Maybe just extract the binary searching
      logic from binary_search_perforce.py and put it in its own module in
      cros_utils?

   2. Cleanup unit tests in ./test. These tests are a little hacked together,
      and are all under one test suite. Maybe consider organizing them across
      multiple directories.

   3. Create a "checkout setup" system for bisection. Currently if you want to
      bisect, you have to run scripts/edit sources in this repo. Ideally these
      scripts would be static, and if you wanted to bisect/make changes you would
      "checkout" or copy all the scripts to a working directory and have a unique
      working directory for each bisection. Credits to Luis for this idea =)

   4. Make all scripts relative to each other. Currently all scripts enforce the
      idea that their cwd will be ./binary_search_tool/. But it would be less
      confusing to have each script relative to each other. There's quite a few
      stackoverflow topics on how to do this best, but each one has some sort of
      downside or flaw.

   5. Overall modularize code more, especially in binary_search_state.py

 DESIGN EXPLANATIONS:
 Some of the design decisions are a bit difficult to understand from just reading
 the code unfortunately. I will attempt to clear up the major offenders of this:

   1. common.py's argument dictionary:
      binary_search_state.py and run_bisect.py both have to have near identical
      arguments in order to support argument overriding in run_bisect.py. However
      they do have to be slightly different. Mainly, run_bisect.py needs to have
      no default values for arguments (so it can determine what's being
      overriden).

      In order to reduce huge amounts of code duplication for the argument
      building, we put argument building in common.py. That way both modules
      can reference the arguments, and they can have different configurations
      across both.

   2. Compiler wrapper:
      The compiler wrapper is called before all compiler calls. It exists to
      trick whatever build system (make, emerge, etc.) into thinking our
      bisection is just a normal build, when really we're doing some tricks.

      The biggest benefit the compiler wrapper gives is: knowing for sure which
      files are actually generated by the compiler during bisection setup, and
      potentially being able to skip compilations while triaging (speeding up the
      triaging process significantly).

   3. The weird options for the --verify, --verbose, --file_args, etc. arguments:
      Some of the arguments for the bisection tool have a weird set of options
      for the AddArgument method (nargs, const, default, StrToBool). This is so
      we can make argument overriding workable. These options allow the following
      functionality for a boolean argument (using --prune as an example):
        * --prune (prune set to True)
        * <not given> (prune set to False)
        * --prune=True (prune set to True)
        * --prune=False (prune set to False)

      The first two are easy to implement (action='store_true'), but the last two
      are why the extra weird arguments are required. Now, why would we want the
      last two? Imagine if the Android bisector set --prune=True as a default
      argument. With just the first two options above it would be impossible for
      the user to override prune and set it to False. So the user needs the
      --prune=False option. See the argparse documentation for more details.

   4. General binary searching logic/pruning logic:
      binary_search_state.py will enumerate all items into a list. The binary
      search will find the *first* bad item (starting with lowest index).
      Everything to the left of the "current" index is switched to good,
      everything to right of the "current" index is switched to bad. Once a bad
      item is found, it's put at the very end of the list.

      If prune is set, the tool will continuing searching until all bad items are
      found (instead of stopping after the first one). If the tool finds the same
      item twice, that means no more bad items exist. This is because the item
      was found, said item was put at the end of the list, and it was found
      again. Because the binary search logic finds the bad item with the lowest
      index, this means nothing in between the start of the list and the end of
      the list is bad (thus no more bad items remain).
	# Copyright 2020 The Chromium OS Authors. All rights reserved.
	# Use of this source code is governed by a BSD-style license that can be
	# found in the LICENSE file.

	This document is for future maintainers of the binary search/bisection tools.

	Authors:
	* Original Tool: asharif@, llozano@, cmtice@
	* Updates after May 2016: cburden@
	* chromeos-toolchain@

	The following are good reference materials on how the tool works:
	* Ahmad's original presentation:
	https://goto.google.com/zxdfyi

	* Bisection tool update design doc:
	https://goto.google.com/zcwei

	* Bisection tool webpage:
	https://goto.google.com/ruwpyi

	* Compiler wrapper webpage:
	https://goto.google.com/xossn


	TESTING:
	All unit tests live under the ./test directory. However, these tests
	specifically test binary_search_state.py, binary_search_perforce.py,
	run_bisect.py.

	These unit tests will not test the specific logic for ChromeOS/Android
	bisection. To test the ChromeOS/Android bisectors, use the common/hash_test.sh
	test. This is a simple test case that just checks the hashes of files on your
	file system. This means you won't have to find a specific compiler error for
	the bisector to triage in order to test each bisector.

	TODO:
	The bisection tool (I believe) is in a fairly good state. So these are mostly
	wishlist items and things that could use some improvement.

	1. Get rid of binary_search_perforce.py. This file is mostly legacy code and
	the majority of it isn't even used to bisect object files. The file was
	originally intended to bisect CLs, and binary_search_state.py just reused
	the binary searching logic from it. Maybe just extract the binary searching
	logic from binary_search_perforce.py and put it in its own module in
	cros_utils?

	2. Cleanup unit tests in ./test. These tests are a little hacked together,
	and are all under one test suite. Maybe consider organizing them across
	multiple directories.

	3. Create a "checkout setup" system for bisection. Currently if you want to
	bisect, you have to run scripts/edit sources in this repo. Ideally these
	scripts would be static, and if you wanted to bisect/make changes you would
	"checkout" or copy all the scripts to a working directory and have a unique
	working directory for each bisection. Credits to Luis for this idea =)

	4. Make all scripts relative to each other. Currently all scripts enforce the
	idea that their cwd will be ./binary_search_tool/. But it would be less
	confusing to have each script relative to each other. There's quite a few
	stackoverflow topics on how to do this best, but each one has some sort of
	downside or flaw.

	5. Overall modularize code more, especially in binary_search_state.py

	DESIGN EXPLANATIONS:
	Some of the design decisions are a bit difficult to understand from just reading
	the code unfortunately. I will attempt to clear up the major offenders of this:

	1. common.py's argument dictionary:
	binary_search_state.py and run_bisect.py both have to have near identical
	arguments in order to support argument overriding in run_bisect.py. However
	they do have to be slightly different. Mainly, run_bisect.py needs to have
	no default values for arguments (so it can determine what's being
	overriden).

	In order to reduce huge amounts of code duplication for the argument
	building, we put argument building in common.py. That way both modules
	can reference the arguments, and they can have different configurations
	across both.

	2. Compiler wrapper:
	The compiler wrapper is called before all compiler calls. It exists to
	trick whatever build system (make, emerge, etc.) into thinking our
	bisection is just a normal build, when really we're doing some tricks.

	The biggest benefit the compiler wrapper gives is: knowing for sure which
	files are actually generated by the compiler during bisection setup, and
	potentially being able to skip compilations while triaging (speeding up the
	triaging process significantly).

	3. The weird options for the --verify, --verbose, --file_args, etc. arguments:
	Some of the arguments for the bisection tool have a weird set of options
	for the AddArgument method (nargs, const, default, StrToBool). This is so
	we can make argument overriding workable. These options allow the following
	functionality for a boolean argument (using --prune as an example):
	* --prune (prune set to True)
	* <not given> (prune set to False)
	* --prune=True (prune set to True)
	* --prune=False (prune set to False)

	The first two are easy to implement (action='store_true'), but the last two
	are why the extra weird arguments are required. Now, why would we want the
	last two? Imagine if the Android bisector set --prune=True as a default
	argument. With just the first two options above it would be impossible for
	the user to override prune and set it to False. So the user needs the
	--prune=False option. See the argparse documentation for more details.

	4. General binary searching logic/pruning logic:
	binary_search_state.py will enumerate all items into a list. The binary
	search will find the first bad item (starting with lowest index).
	Everything to the left of the "current" index is switched to good,
	everything to right of the "current" index is switched to bad. Once a bad
	item is found, it's put at the very end of the list.

	If prune is set, the tool will continuing searching until all bad items are
	found (instead of stopping after the first one). If the tool finds the same
	item twice, that means no more bad items exist. This is because the item
	was found, said item was put at the end of the list, and it was found
	again. Because the binary search logic finds the bad item with the lowest
	index, this means nothing in between the start of the list and the end of
	the list is bad (thus no more bad items remain).