Author: Jerry Zhu (jerryzhu@google.com)
Primary assignee: Brandon Kim (brandonkim@google.com, brandonk)
Other contributors: William A. Kennington III (wak@google.com, wak)
Created: June 9, 2021
Currently, OpenBMC has code that performs I2C reads for sensors that may take longer than desired. These IO operations are currently synchronous, and therefore may block other functions such as IPMI. This project will involve going through OpenBMC repositories (specifically phosphor-hwmon) that may have this drawback currently, and adding an asynchronous interface using the new io_uring library.
io_uring is a new asynchronous framework for Linux I/O interface (added to 5.1 Linux kernel, 5.10 is preferred). It is an upgrade from the previous asynchronous IO called AIO, which had its limitations in context of its usage in sensor reads for OpenBMC.
brandonkim@google.com has previously created a method for preventing sensors from blocking all other sensor reads and D-Bus if they do not report failures quickly enough in the phosphor-hwmon repository (link to change). Internal Google BMC efforts have also focused on introducing the io_uring library to its code.
By using io_uring, the asynchronous sensor reads will need to maintain the same accuracy as the current, synchronous reads in each of the daemons. Potential OpenBMC repositories that will benefit from this library include:
The focus of this project is to add asynchronous sensor reads to the phosphor-hwmon repository, which is easier to implement than adding asynchronous sensor reads into dbus-sensors.
Users will need the ability to choose whether they want to utilize this new asynchronous method of reading sensors, or remain with the traditional, synchronous method. In addition, the performance improvement from using the new io_uring library will need to be calculated for each daemon.
In the phosphor-hwmon repository, the primary files that will require modification are sensor.cpp/.hpp and mainloop.cpp/.hpp, as well the addition of a caching layer for the results from the sensor reads.
In mainloop.cpp currently, the read()
function, which reads hwmon sysfs entries, iterates through all sensors and calls _ioAccess->read(...)
for each one; this operation is potentially blocking.
The refactor will maintain this loop over all sensors, but instead make the read operation non-blocking by using an io_uring wrapper. A caching layer will be used to store the read results, which will be the main access point for obtaining sensor reads in mainloop.cpp.
Interface Layer +--------------------------------------------+ | | | +------------+ +-------------+ | | | | | | | | | Redfish | | IPMI | | | | | | | | | +-----+------+ +-------+-----+ | | ^ ^ | +---------|------------------------|---------+ | | v v +---------+------------------------+---------+ | | | DBus | | | +---------^------------------------^---------+ | | +-------v-------+ +--------v-------+ | | | | |phosphor-hwmon | | dbus-sensors | | | | | +-------^-------+ +--------^-------+ | <--------------------- | <------- caching layer at this level +--------v------------------------v--------+ | | | Linux kernel | | | +----------^---------------------^---------+ | | +----v-----+ +-----v----+ | | | | |i2c sensor| |i2c sensor| | | | | +----------+ +----------+
Using a flag variable (most likely to be placed in the .conf files of each hwmon sensor), users will be able to determine whether or not to utilize this new io_uring implementation for compatibility reasons.
The read cache is implemented using an unordered_map
of {sensor hwmon path: read result}. The read result is a struct that keeps track of any necessary information for processing the read values and handling errors. Such information includes open file descriptor from the open()
system call, number of retries remaining for reading this sensor when errors occur, etc.
Each call to access the read value of a particular sesnor in the read cache will not only return the cached value but will also submit a SQE (submission queue event) to io_uring for that sensor; this SQE acts as a read request that will be sent to the kernel. The implementation maintains a set of sensors that keeps track of any pre-existing submissions so that multiple SQEs for the same sensor do not get submitted and overlap; the set entries will be cleared upon successful return of the read result using the CQE (completion queue event). The CQE will then be processed, and its information will update the cache map.
The asynchronous nature of this implementation comes from sending all possible SQE requests, a non-blocking operation, at once instead of being blocked by slow sensor reads in the synchronous implementation. The kernel will process these requests, and before the next iteration of sensor reads the cache will attempt to process any returned CQEs, a non-blocking operation as well.
Simply put, an access to some "Sensor A" in the read cache will create an underlying read request that makes a best effort to update the value of "Sensor A" before the next time the sensor read loop (currently 1 s by default) gets the value of "Sensor A" through the cache.
Linux does have a native asynchronous IO interface, simply dubbed AIO; however, there are a number of limitations. The biggest limitation of AIO is that it only supports true asynchronous IO for un-buffered reads. Furthermore, there are a number of ways that the IO submission can end up blocking - for example, if metadata is required to perform IO. Additionally, the memory costs of AIO are more expensive than those of io_uring.
For these primary reasons, the native AIO library will not be considered for this implementation of asynchronous reads.
This project would impact all OpenBMC developers of openbmc/phosphor-hwmon initially. It has improved the latency performance of phosphor-hwmon; throughput has also been shown to increase (note that throughput profiling was more arbitrary than latency profiling). These performance changes will have to be calculated in further detail across different machines.
There will be no security impact.
The change will utilize the gTest framework to ensure the original functionality of the code in the repository modified stays the same.