Improving the clarity of the code

Callers of the function 
pldm_bios_table_attr_value_entry_enum_decode_handles() provide the 
pointer to the buffer and its size. Modifying the buffer size and using 
it in the library can be error-prone. Adjust the code to only read the 
buffer size and not to modify it.

Tested:
Unit Tests passed.

Change-Id: I26e843fa817e969719aa19f1922b4ea8622078f2
Signed-off-by: Archana Kakani <archana.kakani@ibm.com>
2 files changed
tree: b4f08ad32c5601293173f5d03b01d0d56dfd6867
  1. abi/
  2. include/
  3. instance-db/
  4. src/
  5. subprojects/
  6. tests/
  7. .clang-format
  8. .clang-tidy
  9. CHANGELOG.md
  10. LICENSE
  11. meson.build
  12. meson.options
  13. OWNERS
  14. README.md
README.md

libpldm

This is a library which deals with the encoding and decoding of PLDM messages. It should be possible to use this library by projects other than OpenBMC, and hence certain constraints apply to it:

  • keeping it light weight
  • implementation in C
  • minimal dynamic memory allocations
  • endian-safe
  • no OpenBMC specific dependencies

Source files are named according to the PLDM Type, for eg base.[h/c], fru.[h/c], etc.

Given a PLDM command "foo", the library will provide the following API: For the Requester function:

encode_foo_req() - encode a foo request
decode_foo_resp() - decode a response to foo

For the Responder function:

decode_foo_req() - decode a foo request
encode_foo_resp() - encode a response to foo

The library also provides API to pack and unpack PLDM headers.

To Build

Need meson and ninja. Alternatively, source an OpenBMC ARM/x86 SDK.

meson setup builddir && ninja -C builddir

To run unit tests

The simplest way of running the tests is as described by the meson man page:

meson setup builddir && meson test -C builddir

Working with libpldm

The ABIs (symbols, generally functions) exposed by the library are separated into three categories:

  1. Stable
  2. Testing
  3. Deprecated

Applications depending on libpldm should aim to only use functions from the stable category. However, this may not always be possible. What to do when required functions fall into the deprecated or testing categories is outlined below.

What does it mean to mark a function as stable?

Marking a function as stable makes the following promise to users of the library:

We will not remove or change the symbol name, argument count, argument types, return type, or interpretation of relevant values for the function before first marking it as LIBPLDM_ABI_DEPRECATED and then subsequently creating a tagged release

Marking a function as stable does not promise that it is free of implementation bugs. It is just a promise that the prototype won't change without notice.

Given this, it is always okay to implement functions marked stable in terms of functions marked testing inside of libpldm. If we remove or change the prototype of a function marked testing the only impact is that we need to fix up any call sites of that function in the same patch.

The ABI lifecycle

---
title: libpldm symbol lifecycle
---
stateDiagram-v2
    direction LR
    [*] --> Testing: Add
    Testing --> Testing: Change
    Testing --> [*]: Remove
    Testing --> Stable: Stabilise
    Stable --> Deprecated: Deprecate
    Deprecated --> [*]: Remove

The ABI of the library produced by the build is controlled using the abi meson option. The following use cases determine how the abi option should be specified:

Use CaseMeson Configuration
Production-Dabi=deprecated,stable
Maintenance-Dabi=stable
Development-Dabi=deprecated,stable,testing

Maintenance

Applications and libraries that depend on libpldm can identify how to migrate off of deprecated APIs by constraining the library ABI to the stable category. This will force the compiler identify any call-sites that try to link against deprecated symbols.

Development

Applications and libraries often require functionality that doesn't yet exist in libpldm. The work is thus in two parts:

  1. Add the required APIs to libpldm
  2. Use the new APIs from libpldm in the dependent application or library

Adding APIs to a library is a difficult task. Generally, once an API is exposed in the library's ABI, any changes to the API risk breaking applications already making use of it. To make sure we have more than one shot at getting an API right, all new APIs must first be exposed in the testing category. Concretely:

Patches adding new APIs MUST mark them as testing and MUST NOT mark them as stable.

Marking functions as testing, stable or deprecated

Three macros are provided through config.h (automatically included for all translation units) to mark functions as testing, stable or deprecated:

  1. LIBPLDM_ABI_TESTING
  2. LIBPLDM_ABI_STABLE
  3. LIBPLDM_ABI_DEPRECATED

These annotations go immediately before your function signature:

LIBPLDM_ABI_TESTING
pldm_requester_rc_t pldm_transport_send_msg(struct pldm_transport *transport,
					    pldm_tid_t tid,
					    const void *pldm_req_msg,
					    size_t req_msg_len)
{
    ...
}

Requirements for stabilising a function

As mentioned above, all new functions must first be added in the testing category (using the LIBPLDM_ABI_TESTING annotation).

To move a function from the testing category to the stable category, its required that patches demonstrating use of the function in a dependent application or library be linked in the commit message of the stabilisation change. We require this to demonstrate that the implementer has considered its use in context before preventing us from making changes to the API.

Building a dependent application or library against a testing ABI

Meson is broadly used in the OpenBMC ecosystem, the historical home of libpldm. Meson's subprojects are a relatively painless way of managing dependencies for the purpose of developing complex applications and libraries. Use of libpldm as a subproject is both supported and encouraged.

libpldm's ABI can be controlled from a parent project through meson's subproject configuration syntax:

$ meson setup ... -Dlibpldm:abi=deprecated,stable,testing ...

OEM/vendor-specific functions

This will support OEM or vendor-specific functions and semantic information. Following directory structure has to be used:

 libpldm
    |---- include/libpldm
    |        |---- oem/<oem_name>/libpldm
    |                    |----<oem based .h files>
    |---- src
    |        |---- oem/<oem_name>
    |                    |----<oem based .c files>
    |---- tests
    |        |---- oem/<oem_name>
    |                    |----<oem based test files>

<oem_name> - This folder must be created with the name of the OEM/vendor in lower case.

Header files & source files having the oem functionality for the libpldm library should be placed under the respective folder hierarchy as mentioned in the above figure. They must be adhering to the rules mentioned under the libpldm section above.

Once the above is done a meson option has to be created in meson.options with its mapped compiler flag to enable conditional compilation.

For consistency would recommend using "oem-<oem_name>".

The meson.build and the corresponding source file(s) will need to incorporate the logic of adding its mapped compiler flag to allow conditional compilation of the code.

Requester APIs

The pldm requester API's are present in src/requester folder and they are intended to provide API's to interact with the desired underlying transport layer to send/receive pldm messages.

NOTE : In the current state, the requester API's in the repository only works with specific transport mechanism & these are going to change in future & probably aren't appropriate to be writing code against.