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As OpenBMC is intended to be deployed on an embedded system, care should be taken to avoid expensive constructs, and memory usage. In general, our performance and metric targets are:
- Binaries and static files should take up < 1MB of filesystem size
- Memory usage should remain below 10MB at all times
- Application startup time should be less than 1 second on target hardware (AST2500)
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Care should be taken to ensure that all code is written to be asynchronous in nature, to avoid blocking methods from stopping the processing of other tasks. At this time the webserver uses boost::asio for it async framework. Threads should be avoided if possible, and instead use async tasks within boost::asio.
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Secure coding practices should be followed in all places in the webserver
In general, this means:
- All buffer boundaries must be checked before indexing or using values
- All pointers and iterators must be checked for null before dereferencing
- All input from outside the application is considered untrusted, and should be escaped, authorized and filtered accordingly. This includes files in the filesystem.
- All error statuses are checked and accounted for in control flow.
- Where applicable, noexcept methods should be preferred to methods that use exceptions
- Explicitly bounded types should be preferred over implicitly bounded types (like std::array<int, size> as opposed to int[size])
- no use of Banned functions
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Error handling should be constructed in such a way that all possible errors return valid HTTP responses. The following HTTP codes will be used commonly
- 200 OK - Request was properly handled
- 201 Created - Resource was created
- 401 Unauthorized - Request didn't posses the necessary authentication
- 403 Forbidden - Request was authenticated, but did not have the necessary permissions to accomplish the requested task
- 404 Not found - The url was not found
- 500 Internal error - Something has broken within the OpenBMC web server, and should be filed as a bug
Where possible, 307 and 308 redirects should be avoided, as they introduce the possibility for subtle security bugs.
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Given that the most common target of OpenBMC is an ARM11 processor, care needs to be taken to ensure startup times are low. In general this means:
- Minimizing the number of files read from disk at startup. Unless a feature is explicitly intended to be runtime configurable, its logic should be "baked in" to the application at compile time. For cases where the implementation is configurable at runtime, the default values should be included in application code to minimize the use of nonvolatile storage.
- Avoid excessive memory usage and mallocs at startup.
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- At this point in time, the webserver sets a number of security flags in compile time options to prevent misuse. The specific flags and what optimization levels they are enabled at are documented in the CMakeLists.txt file.
- Exceptions are currently enabled for webserver builds, but their use is discouraged. Long term, the intent is to disable exceptions, so any use of them for explicit control flow will likely be rejected in code review. Any use of exceptions should be cases where the program can be reasonably expected to crash if the exception occurs, as this will be the future behavior once exceptions are disabled.
- Run time type information is disabled
- Link time optimization is enabled
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The webserver shall provide the following authentication mechanisms.
- Basic authentication
- Cookie authentication
- Token authentication
There shall be connection between the authentication mechanism used and resources that are available over it. The webserver shall employ an authentication scheme that is in line with the rest of OpenBMC, and allows users and privileges to be provisioned from other interfaces.
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The OpenBMC webserver shall follow the latest OWASP recommendations for authentication, session management, and security.
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The performance priorities for the OpenBMC webserver are (in order):
- Code is readable and clear
- Code follows secure guidelines
- Code is performant, and does not unnecessarily abstract concepts at the expense of performance
- Code does not employ constructs which require continuous system resources, unless required to meet performance targets. (example: caching sensor values which are expected to change regularly)
In general, the OpenBMC webserver is built using the data driven design. Abstraction and Interface guarantees should be used when multiple implementations exist, but for implementations where only a single implementation exists, prefer to make the code correct and clean rather than implement a concrete interface.
The webserver should be capable of hosting phosphor-webui, and implementing the required flows to host the application. In general, all access methods should be available to the webui.
bmcweb's Redfish implementation, including Redfish OEM Resources, shall conform to the Redfish specification. Please keep bmcweb's Redfish support document updated. OEM schemas should conform and be developed in line with the rules in OEM SCHEMAS.
A number of examples of common errors are captured in the common errors doc. It is recommended that developers read and understand all of them before starting any openbmc development. Common Errors.
There are a variety of ways to develop and test bmcweb software changes. Here are the steps for using the SDK and QEMU.
- Follow all development environment setup directions in the development environment setup document. This will get QEMU started up and you in the SDK environment.
- Follow all of the gerrit setup directions in the gerrit setup document.
- Clone bmcweb from gerrit
git clone ssh://openbmc.gerrit/openbmc/bmcweb/
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Follow directions in README.md to compile
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Reduce binary size by stripping it when ready for testing
arm-openbmc-linux-gnueabi-strip bmcweb
Note: Stripping is not required and having the debug symbols could be useful depending on your testing. Leaving them will drastically increase your transfer time to the BMC.
- Copy your bmcweb you want to test to /tmp/ in QEMU
scp -P 2222 bmcweb [email protected]:/tmp/
Special Notes: The address and port shown here (127.0.0.1 and 2222) reaches the QEMU session you set up in your development environment as described above.
- Stop bmcweb service within your QEMU session
systemctl stop bmcweb
Note: bmcweb supports being started directly in parallel with the bmcweb running as a service. The standalone bmcweb will be available on port 18080. An advantage of this is you can compare between the two easily for testing. In QEMU you would need to open up port 18080 when starting QEMU. Your curl commands would need to use 18080 to communicate.
- If running within a system that has read-only /usr/ filesystem, issue the following commands one time per QEMU boot to make the filesystem writeable
mkdir -p /var/persist/usr
mkdir -p /var/persist/work/usr
mount -t overlay -o lowerdir=/usr,upperdir=/var/persist/usr,workdir=/var/persist/work/usr overlay /usr
- Remove the existing bmcweb from the filesystem in QEMU
rm /usr/bin/bmcweb
- Link to your new bmcweb in /tmp/
ln -sf /tmp/bmcweb /usr/bin/bmcweb
- Test your changes. bmcweb will be started automatically upon your first REST or Redfish command
curl -c cjar -b cjar -k -X POST https://127.0.0.1:2443/login -d "{\"data\": [ \"root\", \"0penBmc\" ] }"
curl -c cjar -b cjar -k -X GET https://127.0.0.1:2443/xyz/openbmc_project/state/bmc0
- Stop the bmcweb service and scp new file over to /tmp/ each time you want to retest a change.
See the REST and Redfish cheatsheets for valid commands.
Please test all Redfish changes with the Redfish Service Validator. Your change should not introduce any new validator errors. Please include the Redfish Service Validator results as part of the commit message "Tested" field.
clang-tidy is a tool that can be used to identify coding style violations, bad design patterns, and bug prone constructs. The checks are implemented in the .clang-tidy file in the root of bmcweb, and are expected to be passing. To run, the best way is to run the checks in yocto.
# check out meta-clang in your openbmc root
cd openbmc
git clone https://github.com/kraj/meta-clang
# add the meta-clang layer to BBLAYERS in $BBPATH/conf/bblayers.conf
<path_to_your_build_dir>/meta-clang
# Add this line to $BBPATH/conf/local.conf to build bmcweb with clang
TOOLCHAIN_pn-bmcweb = "clang"
# and build
bitbake bmcweb
# Open devshell (this will open a shell)
bitbake -c devshell bmcweb
# cd into the work dir
cd oe-workdir/bmcweb-1.0+git999
# run clang tidy
clang-tidy --header-filter=".*" -p . $BBPATH/workspace/sources/bmcweb/src/webserver_main.cpp