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+# AV1 Codec Library
+
+## Contents
+1. [Building the lib and applications](#building-the-library-and-applications)
+    - [Prerequisites](#prerequisites)
+    - [Get the code](#get-the-code)
+    - [Basics](#basic-build)
+    - [Configuration options](#configuration-options)
+    - [Dylib builds](#dylib-builds)
+    - [Debugging](#debugging)
+    - [Cross compiling](#cross-compiling)
+    - [Sanitizer support](#sanitizers)
+    - [MSVC builds](#microsoft-visual-studio-builds)
+    - [Xcode builds](#xcode-builds)
+    - [Emscripten builds](#emscripten-builds)
+    - [Extra Build Flags](#extra-build-flags)
+2. [Testing the library](#testing-the-av1-codec)
+    - [Basics](#testing-basics)
+        - [Unit tests](#1_unit-tests)
+        - [Example tests](#2_example-tests)
+        - [Encoder tests](#3_encoder-tests)
+    - [IDE hosted tests](#ide-hosted-tests)
+    - [Downloading test data](#downloading-the-test-data)
+    - [Adding a new test data file](#adding-a-new-test-data-file)
+    - [Additional test data](#additional-test-data)
+    - [Sharded testing](#sharded-testing)
+        - [Running tests directly](#1_running-test_libaom-directly)
+        - [Running tests via CMake](#2_running-the-tests-via-the-cmake-build)
+3. [Coding style](#coding-style)
+4. [Submitting patches](#submitting-patches)
+    - [Login cookie](#login-cookie)
+    - [Contributor agreement](#contributor-agreement)
+    - [Testing your code](#testing-your-code)
+    - [Commit message hook](#commit-message-hook)
+    - [Upload your change](#upload-your-change)
+    - [Incorporating Reviewer Comments](#incorporating-reviewer-comments)
+    - [Submitting your change](#submitting-your-change)
+    - [Viewing change status](#viewing-the-status-of-uploaded-changes)
+5. [Support](#support)
+6. [Bug reports](#bug-reports)
+
+## Building the library and applications
+
+### Prerequisites
+
+ 1. [CMake](https://cmake.org) version 3.5 or higher.
+ 2. [Git](https://git-scm.com/).
+ 3. [Perl](https://www.perl.org/).
+ 4. For x86 targets, [yasm](http://yasm.tortall.net/), which is preferred, or a
+    recent version of [nasm](http://www.nasm.us/).
+ 5. Building the documentation requires [doxygen](http://doxygen.org).
+ 6. Building the unit tests requires [Python](https://www.python.org/).
+ 7. Emscripten builds require the portable
+   [EMSDK](https://kripken.github.io/emscripten-site/index.html).
+
+### Get the code
+
+The AV1 library source code is stored in the Alliance for Open Media Git
+repository:
+
+~~~
+    $ git clone https://aomedia.googlesource.com/aom
+    # By default, the above command stores the source in the aom directory:
+    $ cd aom
+~~~
+
+### Basic build
+
+CMake replaces the configure step typical of many projects. Running CMake will
+produce configuration and build files for the currently selected CMake
+generator. For most systems the default generator is Unix Makefiles. The basic
+form of a makefile build is the following:
+
+~~~
+    $ cmake path/to/aom
+    $ make
+~~~
+
+The above will generate a makefile build that produces the AV1 library and
+applications for the current host system after the make step completes
+successfully. The compiler chosen varies by host platform, but a general rule
+applies: On systems where cc and c++ are present in $PATH at the time CMake is
+run the generated build will use cc and c++ by default.
+
+### Configuration options
+
+The AV1 codec library has a great many configuration options. These come in two
+varieties:
+
+ 1. Build system configuration options. These have the form `ENABLE_FEATURE`.
+ 2. AV1 codec configuration options. These have the form `CONFIG_FEATURE`.
+
+Both types of options are set at the time CMake is run. The following example
+enables ccache and disables the AV1 encoder:
+
+~~~
+    $ cmake path/to/aom -DENABLE_CCACHE=1 -DCONFIG_AV1_ENCODER=0
+    $ make
+~~~
+
+The available configuration options are too numerous to list here. Build system
+configuration options can be found at the top of the CMakeLists.txt file found
+in the root of the AV1 repository, and AV1 codec configuration options can
+currently be found in the file `build/cmake/aom_config_defaults.cmake`.
+
+### Dylib builds
+
+A dylib (shared object) build of the AV1 codec library can be enabled via the
+CMake built in variable `BUILD_SHARED_LIBS`:
+
+~~~
+    $ cmake path/to/aom -DBUILD_SHARED_LIBS=1
+    $ make
+~~~
+
+This is currently only supported on non-Windows targets.
+
+### Debugging
+
+Depending on the generator used there are multiple ways of going about
+debugging AV1 components. For single configuration generators like the Unix
+Makefiles generator, setting `CMAKE_BUILD_TYPE` to Debug is sufficient:
+
+~~~
+    $ cmake path/to/aom -DCMAKE_BUILD_TYPE=Debug
+~~~
+
+For Xcode, mainly because configuration controls for Xcode builds are buried two
+configuration windows deep and must be set for each subproject within the Xcode
+IDE individually, `CMAKE_CONFIGURATION_TYPES` should be set to Debug:
+
+~~~
+    $ cmake path/to/aom -G Xcode -DCMAKE_CONFIGURATION_TYPES=Debug
+~~~
+
+For Visual Studio the in-IDE configuration controls should be used. Simply set
+the IDE project configuration to Debug to allow for stepping through the code.
+
+In addition to the above it can sometimes be useful to debug only C and C++
+code. To disable all assembly code and intrinsics set `AOM_TARGET_CPU` to
+generic at generation time:
+
+~~~
+    $ cmake path/to/aom -DAOM_TARGET_CPU=generic
+~~~
+
+### Cross compiling
+
+For the purposes of building the AV1 codec and applications and relative to the
+scope of this guide, all builds for architectures differing from the native host
+architecture will be considered cross compiles. The AV1 CMake build handles
+cross compiling via the use of toolchain files included in the AV1 repository.
+The toolchain files available at the time of this writing are:
+
+ - arm64-ios.cmake
+ - arm64-linux-gcc.cmake
+ - arm64-mingw-gcc.cmake
+ - armv7-ios.cmake
+ - armv7-linux-gcc.cmake
+ - armv7-mingw-gcc.cmake
+ - armv7s-ios.cmake
+ - mips32-linux-gcc.cmake
+ - mips64-linux-gcc.cmake
+ - x86-ios-simulator.cmake
+ - x86-linux.cmake
+ - x86-macos.cmake
+ - x86-mingw-gcc.cmake
+ - x86\_64-ios-simulator.cmake
+ - x86\_64-mingw-gcc.cmake
+
+The following example demonstrates use of the x86-macos.cmake toolchain file on
+a x86\_64 MacOS host:
+
+~~~
+    $ cmake path/to/aom \
+      -DCMAKE_TOOLCHAIN_FILE=path/to/aom/build/cmake/toolchains/x86-macos.cmake
+    $ make
+~~~
+
+To build for an unlisted target creation of a new toolchain file is the best
+solution. The existing toolchain files can be used a starting point for a new
+toolchain file since each one exposes the basic requirements for toolchain files
+as used in the AV1 codec build.
+
+As a temporary work around an unoptimized AV1 configuration that builds only C
+and C++ sources can be produced using the following commands:
+
+~~~
+    $ cmake path/to/aom -DAOM_TARGET_CPU=generic
+    $ make
+~~~
+
+In addition to the above it's important to note that the toolchain files
+suffixed with gcc behave differently than the others. These toolchain files
+attempt to obey the $CROSS environment variable.
+
+### Sanitizers
+
+Sanitizer integration is built-in to the CMake build system. To enable a
+sanitizer, add `-DSANITIZE=<type>` to the CMake command line. For example, to
+enable address sanitizer:
+
+~~~
+    $ cmake path/to/aom -DSANITIZE=address
+    $ make
+~~~
+
+Sanitizers available vary by platform, target, and compiler. Consult your
+compiler documentation to determine which, if any, are available.
+
+### Microsoft Visual Studio builds
+
+Building the AV1 codec library in Microsoft Visual Studio is supported. The
+following example demonstrates generating projects and a solution for the
+Microsoft IDE:
+
+~~~
+    # This does not require a bash shell; command.exe is fine.
+    $ cmake path/to/aom -G "Visual Studio 15 2017"
+~~~
+
+### Xcode builds
+
+Building the AV1 codec library in Xcode is supported. The following example
+demonstrates generating an Xcode project:
+
+~~~
+    $ cmake path/to/aom -G Xcode
+~~~
+
+### Emscripten builds
+
+Building the AV1 codec library with Emscripten is supported. Typically this is
+used to hook into the AOMAnalyzer GUI application. These instructions focus on
+using the inspector with AOMAnalyzer, but all tools can be built with
+Emscripten.
+
+It is assumed here that you have already downloaded and installed the EMSDK,
+installed and activated at least one toolchain, and setup your environment
+appropriately using the emsdk\_env script.
+
+1. Download [AOMAnalyzer](https://people.xiph.org/~mbebenita/analyzer/).
+
+2. Configure the build:
+
+~~~
+    $ cmake path/to/aom \
+        -DENABLE_CCACHE=1 \
+        -DAOM_TARGET_CPU=generic \
+        -DENABLE_DOCS=0 \
+        -DENABLE_TESTS=0 \
+        -DCONFIG_ACCOUNTING=1 \
+        -DCONFIG_INSPECTION=1 \
+        -DCONFIG_MULTITHREAD=0 \
+        -DCONFIG_RUNTIME_CPU_DETECT=0 \
+        -DCONFIG_WEBM_IO=0 \
+        -DCMAKE_TOOLCHAIN_FILE=path/to/emsdk-portable/.../Emscripten.cmake
+~~~
+
+3. Build it: run make if that's your generator of choice:
+
+~~~
+    $ make inspect
+~~~
+
+4. Run the analyzer:
+
+~~~
+    # inspect.js is in the examples sub directory of the directory in which you
+    # executed cmake.
+    $ path/to/AOMAnalyzer path/to/examples/inspect.js path/to/av1/input/file
+~~~
+
+### Extra build flags
+
+Three variables allow for passing of additional flags to the build system.
+
+- AOM\_EXTRA\_C\_FLAGS
+- AOM\_EXTRA\_CXX\_FLAGS
+- AOM\_EXTRA\_EXE\_LINKER\_FLAGS
+
+The build system attempts to ensure the flags passed through the above variables
+are passed to tools last in order to allow for override of default behavior.
+These flags can be used, for example, to enable asserts in a release build:
+
+~~~
+    $ cmake path/to/aom \
+        -DCMAKE_BUILD_TYPE=Release \
+        -DAOM_EXTRA_C_FLAGS=-UNDEBUG \
+        -DAOM_EXTRA_CXX_FLAGS=-UNDEBUG
+~~~
+
+## Testing the AV1 codec
+
+### Testing basics
+
+There are several methods of testing the AV1 codec. All of these methods require
+the presence of the AV1 source code and a working build of the AV1 library and
+applications.
+
+#### 1. Unit tests:
+
+The unit tests can be run at build time:
+
+~~~
+    # Before running the make command the LIBAOM_TEST_DATA_PATH environment
+    # variable should be set to avoid downloading the test files to the
+    # cmake build configuration directory.
+    $ cmake path/to/aom
+    # Note: The AV1 CMake build creates many test targets. Running make
+    # with multiple jobs will speed up the test run significantly.
+    $ make runtests
+~~~
+
+#### 2. Example tests:
+
+The example tests require a bash shell and can be run in the following manner:
+
+~~~
+    # See the note above about LIBAOM_TEST_DATA_PATH above.
+    $ cmake path/to/aom
+    $ make
+    # It's best to build the testdata target using many make jobs.
+    # Running it like this will verify and download (if necessary)
+    # one at a time, which takes a while.
+    $ make testdata
+    $ path/to/aom/test/examples.sh --bin-path examples
+~~~
+
+#### 3. Encoder tests:
+
+When making a change to the encoder run encoder tests to confirm that your
+change has a positive or negligible impact on encode quality. When running these
+tests the build configuration should be changed to enable internal encoder
+statistics:
+
+~~~
+    $ cmake path/to/aom -DCONFIG_INTERNAL_STATS=1
+    $ make
+~~~
+
+The repository contains scripts intended to make running these tests as simple
+as possible. The following example demonstrates creating a set of baseline clips
+for comparison to results produced after making your change to libaom:
+
+~~~
+    # This will encode all Y4M files in the current directory using the
+    # settings specified to create the encoder baseline statistical data:
+    $ cd path/to/test/inputs
+    # This command line assumes that run_encodes.sh, its helper script
+    # best_encode.sh, and the aomenc you intend to test are all within a
+    # directory in your PATH.
+    $ run_encodes.sh 200 500 50 baseline
+~~~
+
+After making your change and creating the baseline clips, you'll need to run
+encodes that include your change(s) to confirm that things are working as
+intended:
+
+~~~
+    # This will encode all Y4M files in the current directory using the
+    # settings specified to create the statistical data for your change:
+    $ cd path/to/test/inputs
+    # This command line assumes that run_encodes.sh, its helper script
+    # best_encode.sh, and the aomenc you intend to test are all within a
+    # directory in your PATH.
+    $ run_encodes.sh 200 500 50 mytweak
+~~~
+
+After creating both data sets you can use `test/visual_metrics.py` to generate a
+report that can be viewed in a web browser:
+
+~~~
+    $ visual_metrics.py metrics_template.html "*stt" baseline mytweak \
+      > mytweak.html
+~~~
+
+You can view the report by opening mytweak.html in a web browser.
+
+
+### IDE hosted tests
+
+By default the generated projects files created by CMake will not include the
+runtests and testdata rules when generating for IDEs like Microsoft Visual
+Studio and Xcode. This is done to avoid intolerably long build cycles in the
+IDEs-- IDE behavior is to build all targets when selecting the build project
+options in MSVS and Xcode. To enable the test rules in IDEs the
+`ENABLE_IDE_TEST_HOSTING` variable must be enabled at CMake generation time:
+
+~~~
+    # This example uses Xcode. To get a list of the generators
+    # available, run cmake with the -G argument missing its
+    # value.
+    $ cmake path/to/aom -DENABLE_IDE_TEST_HOSTING=1 -G Xcode
+~~~
+
+### Downloading the test data
+
+The fastest and easiest way to obtain the test data is to use CMake to generate
+a build using the Unix Makefiles generator, and then to build only the testdata
+rule:
+
+~~~
+    $ cmake path/to/aom -G "Unix Makefiles"
+    # 28 is used because there are 28 test files as of this writing.
+    $ make -j28 testdata
+~~~
+
+The above make command will only download and verify the test data.
+
+### Adding a new test data file
+
+First, add the new test data file to the `aom-test-data` bucket of the
+`aomedia-testing` project on Google Cloud Platform. You may need to ask someone
+with the necessary access permissions to do this for you.
+
+NOTE: When a new test data file is added to the `aom-test-data` bucket, its
+"Public access" is initially "Not public". We need to change its
+"Public access" to "Public" by using the following
+[`gsutil`](https://cloud.google.com/storage/docs/gsutil_install) command:
+~~~
+    $ gsutil acl ch -g all:R gs://aom-test-data/test-data-file-name
+~~~
+This command grants the `AllUsers` group READ access to the file named
+"test-data-file-name" in the `aom-test-data` bucket.
+
+Once the new test data file has been added to `aom-test-data`, create a CL to
+add the name of the new test data file to `test/test_data_util.cmake` and add
+the SHA1 checksum of the new test data file to `test/test-data.sha1`. (The SHA1
+checksum of a file can be calculated by running the `sha1sum` command on the
+file.)
+
+### Additional test data
+
+The test data mentioned above is strictly intended for unit testing.
+
+Additional input data for testing the encoder can be obtained from:
+https://media.xiph.org/video/derf/
+
+### Sharded testing
+
+The AV1 codec library unit tests are built upon gtest which supports sharding of
+test jobs. Sharded test runs can be achieved in a couple of ways.
+
+#### 1. Running test\_libaom directly:
+
+~~~
+   # Set the environment variable GTEST_TOTAL_SHARDS to control the number of
+   # shards.
+   $ export GTEST_TOTAL_SHARDS=10
+   # (GTEST shard indexing is 0 based).
+   $ seq 0 $(( $GTEST_TOTAL_SHARDS - 1 )) \
+       | xargs -n 1 -P 0 -I{} env GTEST_SHARD_INDEX={} ./test_libaom
+~~~
+
+To create a test shard for each CPU core available on the current system set
+`GTEST_TOTAL_SHARDS` to the number of CPU cores on your system minus one.
+
+#### 2. Running the tests via the CMake build:
+
+~~~
+    # For IDE based builds, ENABLE_IDE_TEST_HOSTING must be enabled. See
+    # the IDE hosted tests section above for more information. If the IDE
+    # supports building targets concurrently tests will be sharded by default.
+
+    # For make and ninja builds the -j parameter controls the number of shards
+    # at test run time. This example will run the tests using 10 shards via
+    # make.
+    $ make -j10 runtests
+~~~
+
+The maximum number of test targets that can run concurrently is determined by
+the number of CPUs on the system where the build is configured as detected by
+CMake. A system with 24 cores can run 24 test shards using a value of 24 with
+the `-j` parameter. When CMake is unable to detect the number of cores 10 shards
+is the default maximum value.
+
+## Coding style
+
+We are using the Google C Coding Style defined by the
+[Google C++ Style Guide](https://google.github.io/styleguide/cppguide.html).
+
+The coding style used by this project is enforced with clang-format using the
+configuration contained in the
+[.clang-format](https://chromium.googlesource.com/webm/aom/+/master/.clang-format)
+file in the root of the repository.
+
+You can download clang-format using your system's package manager, or directly
+from [llvm.org](http://llvm.org/releases/download.html). You can also view the
+[documentation](https://clang.llvm.org/docs/ClangFormat.html) on llvm.org.
+Output from clang-format varies by clang-format version, for best results your
+version should match the one used on Jenkins. You can find the clang-format
+version by reading the comment in the `.clang-format` file linked above.
+
+Before pushing changes for review you can format your code with:
+
+~~~
+    # Apply clang-format to modified .c, .h and .cc files
+    $ clang-format -i --style=file \
+      $(git diff --name-only --diff-filter=ACMR '*.[hc]' '*.cc')
+~~~
+
+Check the .clang-format file for the version used to generate it if there is any
+difference between your local formatting and the review system.
+
+Some Git installations have clang-format integration. Here are some examples:
+
+~~~
+    # Apply clang-format to all staged changes:
+    $ git clang-format
+
+    # Clang format all staged and unstaged changes:
+    $ git clang-format -f
+
+    # Clang format all staged and unstaged changes interactively:
+    $ git clang-format -f -p
+~~~
+
+## Submitting patches
+
+We manage the submission of patches using the
+[Gerrit](https://www.gerritcodereview.com/) code review tool. This tool
+implements a workflow on top of the Git version control system to ensure that
+all changes get peer reviewed and tested prior to their distribution.
+
+### Login cookie
+
+Browse to [AOMedia Git index](https://aomedia.googlesource.com/) and login with
+your account (Gmail credentials, for example). Next, follow the
+`Generate Password` Password link at the top of the page. You’ll be given
+instructions for creating a cookie to use with our Git repos.
+
+### Contributor agreement
+
+You will be required to execute a
+[contributor agreement](http://aomedia.org/license) to ensure that the AOMedia
+Project has the right to distribute your changes.
+
+### Testing your code
+
+The testing basics are covered in the [testing section](#testing-the-av1-codec)
+above.
+
+In addition to the local tests, many more (e.g. asan, tsan, valgrind) will run
+through Jenkins instances upon upload to gerrit.
+
+### Commit message hook
+
+Gerrit requires that each submission include a unique Change-Id. You can assign
+one manually using git commit --amend, but it’s easier to automate it with the
+commit-msg hook provided by Gerrit.
+
+Copy commit-msg to the `.git/hooks` directory of your local repo. Here's an
+example:
+
+~~~
+    $ curl -Lo aom/.git/hooks/commit-msg https://chromium-review.googlesource.com/tools/hooks/commit-msg
+
+    # Next, ensure that the downloaded commit-msg script is executable:
+    $ chmod u+x aom/.git/hooks/commit-msg
+~~~
+
+See the Gerrit
+[documentation](https://gerrit-review.googlesource.com/Documentation/user-changeid.html)
+for more information.
+
+### Upload your change
+
+The command line to upload your patch looks like this:
+
+~~~
+    $ git push https://aomedia-review.googlesource.com/aom HEAD:refs/for/master
+~~~
+
+### Incorporating reviewer comments
+
+If you previously uploaded a change to Gerrit and the Approver has asked for
+changes, follow these steps:
+
+1. Edit the files to make the changes the reviewer has requested.
+2. Recommit your edits using the --amend flag, for example:
+
+~~~
+   $ git commit -a --amend
+~~~
+
+3. Use the same git push command as above to upload to Gerrit again for another
+   review cycle.
+
+In general, you should not rebase your changes when doing updates in response to
+review. Doing so can make it harder to follow the evolution of your change in
+the diff view.
+
+### Submitting your change
+
+Once your change has been Approved and Verified, you can “submit” it through the
+Gerrit UI. This will usually automatically rebase your change onto the branch
+specified.
+
+Sometimes this can’t be done automatically. If you run into this problem, you
+must rebase your changes manually:
+
+~~~
+    $ git fetch
+    $ git rebase origin/branchname
+~~~
+
+If there are any conflicts, resolve them as you normally would with Git. When
+you’re done, reupload your change.
+
+### Viewing the status of uploaded changes
+
+To check the status of a change that you uploaded, open
+[Gerrit](https://aomedia-review.googlesource.com/), sign in, and click My >
+Changes.
+
+## Support
+
+This library is an open source project supported by its community. Please
+please email aomediacodec@jointdevelopment.kavi.com for help.
+
+## Bug reports
+
+Bug reports can be filed in the Alliance for Open Media
+[issue tracker](https://bugs.chromium.org/p/aomedia/issues/list).