mbox series

[v5,0/4] Generate address range data for built-in modules

Message ID 20240716031045.1781332-1-kris.van.hees@oracle.com (mailing list archive)
Headers show
Series Generate address range data for built-in modules | expand

Message

Kris Van Hees July 16, 2024, 3:10 a.m. UTC
Especially for tracing applications, it is convenient to be able to
refer to a symbol using a <module name, symbol name> pair and to be able
to translate an address into a <nodule mname, symbol name> pair.  But
that does not work if the module is built into the kernel because the
object files that comprise the built-in module implementation are simply
linked into the kernel image along with all other kernel object files.

This is especially visible when providing tracing scripts for support
purposes, where the developer of the script targets a particular kernel
version, but does not have control over whether the target system has
a particular module as loadable module or built-in module.  When tracing
symbols within a module, referring them by <module name, symbol name>
pairs is both convenient and aids symbol lookup.  But that naming will
not work if the module name information is lost if the module is built
into the kernel on the target system.

Earlier work addressing this loss of information for built-in modules
involved adding module name information to the kallsyms data, but that
required more invasive code in the kernel proper.  This work never did
get merged into the kernel tree.

All that is really needed is knowing whether a given address belongs to
a particular module (or multiple modules if they share an object file).
Or in other words, whether that address falls within an address range
that is associated with one or more modules.

Objects can be identified as belonging to a particular module (or
modules) based on defines that are passed as flags to their respective
compilation commands.  The data found in modules.builtin is used to
determine what modules are built into the kernel proper.  Then,
vmlinux.o.map and vmlinux.map can be parsed in a single pass to generate
a modules.buitin.ranges file with offset range information (relative to
the base address of the associated section) for built-in modules.  This
file gets installed along with the other modules.builtin.* files.

The impact on the kernel build is minimal because everything is done
using a single-pass AWK script.  The generated data size is minimal as
well, (depending on the exact kernel configuration) usually in the range
of 500-700 lines, with a file size of 20-40KB (if all modules are built
in, the file contains about 8000 lines, with a file size of about 285KB).

Changes since v4:
 - Improved commit descriptions to explain the why and how.
 - Documented dependency on GNU AWK for CONFIG_BUILTIN_MODULE_RANGES.
 - Improved comments in generate_builtin_ranges.awk
 - Improved logic in generate_builtin_ranges.awk to handle incorrect
   object size information in linker maps
 - Added verify_builtin_ranges.awk

Changes since v3:
 - Consolidated patches 2 through 5 into a single patch
 - Move CONFIG_BUILTIN_MODULE_RANGES to Kconfig.debug
 - Make CONFIG_BUILTIN_MODULE_RANGES select CONFIG_VMLINUX_MAP
 - Disable CONFIG_BUILTIN_MODULE_RANGES if CONFIG_LTO_CLANG_(FULL|THIN)=y
 - Support LLVM (lld) compiles in generate_builtin_ranges.awk
 - Support CONFIG_LD_DEAD_CODE_DATA_ELIMINATION=y
 - Only install modules.builtin.ranges if CONFIG_BUILTIN_MODULE_RANGES=y

Changes since v2:
 - Switched from using modules.builtin.objs to parsing .*.cmd files
 - Add explicit dependency on FTRACE for CONFIG_BUILTIN_MODULE_RANGES
 - 1st arg to generate_builtin_ranges.awk is now modules.builtin.modinfo
 - Parse data from .*.cmd in generate_builtin_ranges.awk
 - Use $(real-prereqs) rather than $(filter-out ...)
 - Include modules.builtin.ranges in modules install target

Changes since v1:
 - Renamed CONFIG_BUILTIN_RANGES to CONFIG_BUILTIN_MODULE_RANGES
 - Moved the config option to the tracers section
 - 2nd arg to generate_builtin_ranges.awk should be vmlinux.map

Kris Van Hees (5):
  trace: add CONFIG_BUILTIN_MODULE_RANGES option
  kbuild: generate a linker map for vmlinux.o
  module: script to generate offset ranges for builtin modules
  kbuild: generate modules.builtin.ranges when linking the kernel
  module: add install target for modules.builtin.ranges

Luis Chamberlain (1):
  kbuild: add modules.builtin.objs

 .gitignore                          |   2 +-
 Documentation/dontdiff              |   2 +-
 Documentation/kbuild/kbuild.rst     |   5 ++
 Makefile                            |   8 +-
 include/linux/module.h              |   4 +-
 kernel/trace/Kconfig                |  17 ++++
 scripts/Makefile.lib                |   5 +-
 scripts/Makefile.modinst            |  11 ++-
 scripts/Makefile.vmlinux            |  17 ++++
 scripts/Makefile.vmlinux_o          |  18 ++++-
 scripts/generate_builtin_ranges.awk | 149 ++++++++++++++++++++++++++++++++++++
 11 files changed, 228 insertions(+), 10 deletions(-)
 create mode 100755 scripts/generate_builtin_ranges.awk


base-commit: dd5a440a31fae6e459c0d6271dddd62825505361

Comments

Steven Rostedt Aug. 14, 2024, 4:45 p.m. UTC | #1
On Mon, 15 Jul 2024 23:10:41 -0400
Kris Van Hees <kris.van.hees@oracle.com> wrote:

> Especially for tracing applications, it is convenient to be able to
> refer to a symbol using a <module name, symbol name> pair and to be able
> to translate an address into a <nodule mname, symbol name> pair.  But
> that does not work if the module is built into the kernel because the
> object files that comprise the built-in module implementation are simply
> linked into the kernel image along with all other kernel object files.
> 
> This is especially visible when providing tracing scripts for support
> purposes, where the developer of the script targets a particular kernel
> version, but does not have control over whether the target system has
> a particular module as loadable module or built-in module.  When tracing
> symbols within a module, referring them by <module name, symbol name>
> pairs is both convenient and aids symbol lookup.  But that naming will
> not work if the module name information is lost if the module is built
> into the kernel on the target system.
> 
> Earlier work addressing this loss of information for built-in modules
> involved adding module name information to the kallsyms data, but that
> required more invasive code in the kernel proper.  This work never did
> get merged into the kernel tree.
> 
> All that is really needed is knowing whether a given address belongs to
> a particular module (or multiple modules if they share an object file).
> Or in other words, whether that address falls within an address range
> that is associated with one or more modules.
> 
> Objects can be identified as belonging to a particular module (or
> modules) based on defines that are passed as flags to their respective
> compilation commands.  The data found in modules.builtin is used to
> determine what modules are built into the kernel proper.  Then,
> vmlinux.o.map and vmlinux.map can be parsed in a single pass to generate
> a modules.buitin.ranges file with offset range information (relative to
> the base address of the associated section) for built-in modules.  This
> file gets installed along with the other modules.builtin.* files.

Hmm, it's hard to parse the above. So the goal is just to make the
modules.builtin.ranges file? If so, that should probably be expressed at
the start, so we know right from the beginning what the result of this is.

  At build time, create the file modules.builtin.ranges that will hold the
  text address of the built-in modules that can be used by tracers.

That just makes it a bit easier to read the rest. I know I'm being a bit
anal on this, but jumping between several different patch series, is making
my head hurt. :-p

But now that I know what you are trying to do, it's now making sense ;-)

-- Steve


> 
> The impact on the kernel build is minimal because everything is done
> using a single-pass AWK script.  The generated data size is minimal as
> well, (depending on the exact kernel configuration) usually in the range
> of 500-700 lines, with a file size of 20-40KB (if all modules are built
> in, the file contains about 8000 lines, with a file size of about 285KB).
>