Message ID | 20240815150339.1564769-3-kris.van.hees@oracle.com (mailing list archive) |
---|---|
State | Superseded |
Headers | show |
Series | Generate address range data for built-in modules | expand |
On Fri, Aug 16, 2024 at 12:04 AM Kris Van Hees <kris.van.hees@oracle.com> wrote: The subject should be: "kbuild: generate offset range data for builtin modules" (Drop ", kconfig") > > Create file module.builtin.ranges that can be used to find where > built-in modules are located by their addresses. This will be useful for > tracing tools to find what functions are for various built-in modules. > > The offset range data for builtin modules is generated using: > - modules.builtin: associates object files with module names > - vmlinux.map: provides load order of sections and offset of first member > per section > - vmlinux.o.map: provides offset of object file content per section > - .*.cmd: build cmd file with KBUILD_MODFILE and KBUILD_MODNAME I do not see "KBUILD_MODNAME" in the code. It only checks "KUILD_MODFILE". > > The generated data will look like: > > .text 00000000-00000000 = _text > .text 0000baf0-0000cb10 amd_uncore > .text 0009bd10-0009c8e0 iosf_mbi > ... > .text 008e6660-008e9630 snd_soc_wcd_mbhc > .text 008e9630-008ea610 snd_soc_wcd9335 snd_soc_wcd934x snd_soc_wcd938x It is good to note that multiple module names appear in one line, but the instance (snd_soc_wcd933*) no longer occurs since 11b0b802f8e38d48ca74d520028add81263f003e. I recommend to replace the output snippet with: .text 00b9f080-00ba011a intel_skl_int3472_discrete .text 00ba0120-00ba03c0 intel_skl_int3472_discrete intel_skl_int3472_tps68470 .text 00ba03c0-00ba08d6 intel_skl_int3472_tps68470 This still happens when CONFIG_INTEL_SKL_INT3472=y. > .text 008ea610-008ea780 snd_soc_wcd9335 > ... > .data 00000000-00000000 = _sdata > .data 0000f020-0000f680 amd_uncore > > For each ELF section, it lists the offset of the first symbol. This can > be used to determine the base address of the section at runtime. > > Next, it lists (in strict ascending order) offset ranges in that section > that cover the symbols of one or more builtin modules. Multiple ranges > can apply to a single module, and ranges can be shared between modules. > > The CONFIG_BUILTIN_MODULE_RANGES option controls whether offset range data > is generated for kernel modules that are built into the kernel image. > > How it works: > > 1. The modules.builtin file is parsed to obtain a list of built-in > module names and their associated object names (the .ko file that > the module would be in if it were a loadable module, hereafter > referred to as <kmodfile>). This object name can be used to > identify objects in the kernel compile because any C or assembler > code that ends up into a built-in module will have the option > -DKBUILD_MODFILE=<kmodfile> present in its build command, and those > can be found in the .<obj>.cmd file in the kernel build tree. > > If an object is part of multiple modules, they will all be listed > in the KBUILD_MODFILE option argument. > > This allows us to conclusively determine whether an object in the > kernel build belong to any modules, and which. > > 2. The vmlinux.map is parsed next to determine the base address of each > top level section so that all addresses into the section can be > turned into offsets. This makes it possible to handle sections > getting loaded at different addresses at system boot. > > We also determine an 'anchor' symbol at the beginning of each > section to make it possible to calculate the true base address of > a section at runtime (i.e. symbol address - symbol offset). > > We collect start addresses of sections that are included in the top > level section. This is used when vmlinux is linked using vmlinux.o, > because in that case, we need to look at the vmlinux.o linker map to > know what object a symbol is found in. > > And finally, we process each symbol that is listed in vmlinux.map > (or vmlinux.o.map) based on the following structure: > > vmlinux linked from vmlinux.a: > > vmlinux.map: > <top level section> > <included section> -- might be same as top level section) > <object> -- built-in association known > <symbol> -- belongs to module(s) object belongs to > ... > > vmlinux linked from vmlinux.o: > > vmlinux.map: > <top level section> > <included section> -- might be same as top level section) > vmlinux.o -- need to use vmlinux.o.map > <symbol> -- ignored > ... > > vmlinux.o.map: > <section> > <object> -- built-in association known > <symbol> -- belongs to module(s) object belongs to > ... > > 3. As sections, objects, and symbols are processed, offset ranges are > constructed in a striaght-forward way: > > - If the symbol belongs to one or more built-in modules: > - If we were working on the same module(s), extend the range > to include this object > - If we were working on another module(s), close that range, > and start the new one > - If the symbol does not belong to any built-in modules: > - If we were working on a module(s) range, close that range > > Signed-off-by: Kris Van Hees <kris.van.hees@oracle.com> > Reviewed-by: Nick Alcock <nick.alcock@oracle.com> > Reviewed-by: Alan Maguire <alan.maguire@oracle.com> > Reviewed-by: Steven Rostedt (Google) <rostedt@goodmis.org> > --- > Changes since v5: > - Removed unnecessary compatibility info from option description. > > Changes since v4: > - Improved commit description 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 > > 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 > > Changes since v2: > - Add explicit dependency on FTRACE for CONFIG_BUILTIN_MODULE_RANGES > - 1st arg to generate_builtin_ranges.awk is now modules.builtin.modinfo > - Switched from using modules.builtin.objs to parsing .*.cmd files > - Parse data from .*.cmd in generate_builtin_ranges.awk > - Use $(real-prereqs) rather than $(filter-out ...) > --- > System utilities > index a30c03a66172..dcdf14ffe031 100644 > --- a/lib/Kconfig.debug > +++ b/lib/Kconfig.debug > @@ -571,6 +571,22 @@ config VMLINUX_MAP > pieces of code get eliminated with > CONFIG_LD_DEAD_CODE_DATA_ELIMINATION. > > +config BUILTIN_MODULE_RANGES > + bool "Generate address range information for builtin modules" > + depends on !LTO_CLANG_FULL > + depends on !LTO_CLANG_THIN > + select VMLINUX_MAP I still got "WARNING: unmet direct dependencies detected for VMLINUX_MAP" I suggested "depends on VMLINUX_MAP" instead of "select VMLINUX_MAP". https://lore.kernel.org/linux-kbuild/202405150623.lmS5sVhM-lkp@intel.com/ https://lore.kernel.org/linux-kbuild/CAK7LNAST_SbaN9WQRM_k0xE1MUReJvn9AMSg4A1-9b9xotf67w@mail.gmail.com/ > + help > + When modules are built into the kernel, there will be no module name > + associated with its symbols in /proc/kallsyms. Tracers may want to > + identify symbols by module name and symbol name regardless of whether > + the module is configured as loadable or not. > + > + This option generates modules.builtin.ranges in the build tree with > + offset ranges (per ELF section) for the module(s) they belong to. > + It also records an anchor symbol to determine the load address of the > + section. > + > config DEBUG_FORCE_WEAK_PER_CPU > bool "Force weak per-cpu definitions" > depends on DEBUG_KERNEL > diff --git a/scripts/Makefile.vmlinux b/scripts/Makefile.vmlinux > index 49946cb96844..7e21162e9de1 100644 > --- a/scripts/Makefile.vmlinux > +++ b/scripts/Makefile.vmlinux > @@ -33,6 +33,22 @@ targets += vmlinux > vmlinux: scripts/link-vmlinux.sh vmlinux.o $(KBUILD_LDS) FORCE > +$(call if_changed_dep,link_vmlinux) > > +# module.builtin.ranges > +# --------------------------------------------------------------------------- > +ifdef CONFIG_BUILTIN_MODULE_RANGES > +__default: modules.builtin.ranges > + > +quiet_cmd_modules_builtin_ranges = GEN $@ > + cmd_modules_builtin_ranges = \ > + $(srctree)/scripts/generate_builtin_ranges.awk $(real-prereqs) > $@ > + > +vmlinux.map: vmlinux This should be: vmlinux.map: vmlinux @: Otherwise, GNU Make would try to find a pattern rule to update vmlinux.map. > + > +targets += modules.builtin.ranges > +modules.builtin.ranges: modules.builtin vmlinux.map vmlinux.o.map FORCE > + $(call if_changed,modules_builtin_ranges) Presumably, modules.builtin.ranges should be regenerated when scripts/generate_builtin_ranges.awk is changed. Maybe, you can do this: quiet_cmd_modules_builtin_ranges = GEN $@ cmd_modules_builtin_ranges = $(real-prereqs) > $@ targets += modules.builtin.ranges modules.builtin.ranges: $(srctree)/scripts/generate_builtin_ranges.awk \ modules.builtin vmlinux.map vmlinux.o.map FORCE $(call if_changed,modules_builtin_ranges) > +endif > + > # Add FORCE to the prequisites of a target to force it to be always rebuilt. > # --------------------------------------------------------------------------- > > diff --git a/scripts/Makefile.vmlinux_o b/scripts/Makefile.vmlinux_o > index 6de297916ce6..252505505e0e 100644 > --- a/scripts/Makefile.vmlinux_o > +++ b/scripts/Makefile.vmlinux_o > @@ -45,9 +45,12 @@ objtool-args = $(vmlinux-objtool-args-y) --link > # Link of vmlinux.o used for section mismatch analysis > # --------------------------------------------------------------------------- > > +vmlinux-o-ld-args-$(CONFIG_BUILTIN_MODULE_RANGES) += -Map=$@.map > + > quiet_cmd_ld_vmlinux.o = LD $@ > cmd_ld_vmlinux.o = \ > $(LD) ${KBUILD_LDFLAGS} -r -o $@ \ > + $(vmlinux-o-ld-args-y) \ > $(addprefix -T , $(initcalls-lds)) \ > --whole-archive vmlinux.a --no-whole-archive \ > --start-group $(KBUILD_VMLINUX_LIBS) --end-group \ > diff --git a/scripts/generate_builtin_ranges.awk b/scripts/generate_builtin_ranges.awk > new file mode 100755 > index 000000000000..9b647781d5fe > --- /dev/null > +++ b/scripts/generate_builtin_ranges.awk > @@ -0,0 +1,515 @@ > +#!/usr/bin/gawk -f > +# SPDX-License-Identifier: GPL-2.0 > +# generate_builtin_ranges.awk: Generate address range data for builtin modules > +# Written by Kris Van Hees <kris.van.hees@oracle.com> > +# > +# Usage: generate_builtin_ranges.awk modules.builtin vmlinux.map \ > +# vmlinux.o.map > modules.builtin.ranges > +# > + > +# Return the module name(s) (if any) associated with the given object. > +# > +# If we have seen this object before, return information from the cache. > +# Otherwise, retrieve it from the corresponding .cmd file. > +# > +function get_module_info(fn, mod, obj, mfn, s) { > + if (fn in omod) > + return omod[fn]; > + > + if (match(fn, /\/[^/]+$/) == 0) > + return ""; > + > + obj = fn; > + mod = ""; > + mfn = ""; > + fn = substr(fn, 1, RSTART) "." substr(fn, RSTART + 1) ".cmd"; > + if (getline s <fn == 1) { > + if (match(s, /DKBUILD_MODFILE=['"]+[^'"]+/) > 0) { > + mfn = substr(s, RSTART + 16, RLENGTH - 16); > + gsub(/['"]/, "", mfn); > + > + mod = mfn; > + gsub(/([^/ ]*\/)+/, "", mod); > + gsub(/-/, "_", mod); > + } > + } > + close(fn); > + > + # A single module (common case) also reflects objects that are not part > + # of a module. Some of those objects have names that are also a module > + # name (e.g. core). We check the associated module file name, and if > + # they do not match, the object is not part of a module. > + if (mod !~ / /) { > + if (!(mod in mods)) > + mod = ""; > + if (mods[mod] != mfn) > + mod = ""; > + } > + > + # At this point, mod is a single (valid) module name, or a list of > + # module names (that do not need validation). > + omod[obj] = mod; > + close(fn); Is this "close(fn)" necessary? I see it a few lines above too. The code became way simpler since my previous review, but I think this is still redundant. You do not need to check both of modname and its path. I attached a patch for code refactoring. -- Best Regards Masahiro Yamada
On Sun, Aug 18, 2024 at 03:19:36PM +0900, Masahiro Yamada wrote: > On Fri, Aug 16, 2024 at 12:04???AM Kris Van Hees <kris.van.hees@oracle.com> wrote: > > > The subject should be: > "kbuild: generate offset range data for builtin modules" > > > (Drop ", kconfig") Thank you - applied. > > > > Create file module.builtin.ranges that can be used to find where > > built-in modules are located by their addresses. This will be useful for > > tracing tools to find what functions are for various built-in modules. > > > > The offset range data for builtin modules is generated using: > > - modules.builtin: associates object files with module names > > - vmlinux.map: provides load order of sections and offset of first member > > per section > > - vmlinux.o.map: provides offset of object file content per section > > - .*.cmd: build cmd file with KBUILD_MODFILE and KBUILD_MODNAME > > > I do not see "KBUILD_MODNAME" in the code. > It only checks "KUILD_MODFILE". Ah yes, that was a leftover from the earlier implementation. Updated. > > > > The generated data will look like: > > > > .text 00000000-00000000 = _text > > .text 0000baf0-0000cb10 amd_uncore > > .text 0009bd10-0009c8e0 iosf_mbi > > ... > > .text 008e6660-008e9630 snd_soc_wcd_mbhc > > .text 008e9630-008ea610 snd_soc_wcd9335 snd_soc_wcd934x snd_soc_wcd938x > > > > It is good to note that multiple module names appear > in one line, but the instance (snd_soc_wcd933*) no longer > occurs since 11b0b802f8e38d48ca74d520028add81263f003e. > > > I recommend to replace the output snippet with: > > > .text 00b9f080-00ba011a intel_skl_int3472_discrete > .text 00ba0120-00ba03c0 intel_skl_int3472_discrete intel_skl_int3472_tps68470 > .text 00ba03c0-00ba08d6 intel_skl_int3472_tps68470 > > > This still happens when CONFIG_INTEL_SKL_INT3472=y. Applied. Thanks for pointing this out - I didn't noticed that the original case was no longer present. > > .text 008ea610-008ea780 snd_soc_wcd9335 > > ... > > .data 00000000-00000000 = _sdata > > .data 0000f020-0000f680 amd_uncore > > > > For each ELF section, it lists the offset of the first symbol. This can > > be used to determine the base address of the section at runtime. > > > > Next, it lists (in strict ascending order) offset ranges in that section > > that cover the symbols of one or more builtin modules. Multiple ranges > > can apply to a single module, and ranges can be shared between modules. > > > > The CONFIG_BUILTIN_MODULE_RANGES option controls whether offset range data > > is generated for kernel modules that are built into the kernel image. > > > > How it works: > > > > 1. The modules.builtin file is parsed to obtain a list of built-in > > module names and their associated object names (the .ko file that > > the module would be in if it were a loadable module, hereafter > > referred to as <kmodfile>). This object name can be used to > > identify objects in the kernel compile because any C or assembler > > code that ends up into a built-in module will have the option > > -DKBUILD_MODFILE=<kmodfile> present in its build command, and those > > can be found in the .<obj>.cmd file in the kernel build tree. > > > > If an object is part of multiple modules, they will all be listed > > in the KBUILD_MODFILE option argument. > > > > This allows us to conclusively determine whether an object in the > > kernel build belong to any modules, and which. > > > > 2. The vmlinux.map is parsed next to determine the base address of each > > top level section so that all addresses into the section can be > > turned into offsets. This makes it possible to handle sections > > getting loaded at different addresses at system boot. > > > > We also determine an 'anchor' symbol at the beginning of each > > section to make it possible to calculate the true base address of > > a section at runtime (i.e. symbol address - symbol offset). > > > > We collect start addresses of sections that are included in the top > > level section. This is used when vmlinux is linked using vmlinux.o, > > because in that case, we need to look at the vmlinux.o linker map to > > know what object a symbol is found in. > > > > And finally, we process each symbol that is listed in vmlinux.map > > (or vmlinux.o.map) based on the following structure: > > > > vmlinux linked from vmlinux.a: > > > > vmlinux.map: > > <top level section> > > <included section> -- might be same as top level section) > > <object> -- built-in association known > > <symbol> -- belongs to module(s) object belongs to > > ... > > > > vmlinux linked from vmlinux.o: > > > > vmlinux.map: > > <top level section> > > <included section> -- might be same as top level section) > > vmlinux.o -- need to use vmlinux.o.map > > <symbol> -- ignored > > ... > > > > vmlinux.o.map: > > <section> > > <object> -- built-in association known > > <symbol> -- belongs to module(s) object belongs to > > ... > > > > 3. As sections, objects, and symbols are processed, offset ranges are > > constructed in a striaght-forward way: > > > > - If the symbol belongs to one or more built-in modules: > > - If we were working on the same module(s), extend the range > > to include this object > > - If we were working on another module(s), close that range, > > and start the new one > > - If the symbol does not belong to any built-in modules: > > - If we were working on a module(s) range, close that range > > > > Signed-off-by: Kris Van Hees <kris.van.hees@oracle.com> > > Reviewed-by: Nick Alcock <nick.alcock@oracle.com> > > Reviewed-by: Alan Maguire <alan.maguire@oracle.com> > > Reviewed-by: Steven Rostedt (Google) <rostedt@goodmis.org> > > --- > > Changes since v5: > > - Removed unnecessary compatibility info from option description. > > > > Changes since v4: > > - Improved commit description 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 > > > > 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 > > > > Changes since v2: > > - Add explicit dependency on FTRACE for CONFIG_BUILTIN_MODULE_RANGES > > - 1st arg to generate_builtin_ranges.awk is now modules.builtin.modinfo > > - Switched from using modules.builtin.objs to parsing .*.cmd files > > - Parse data from .*.cmd in generate_builtin_ranges.awk > > - Use $(real-prereqs) rather than $(filter-out ...) > > --- > > > System utilities > > > index a30c03a66172..dcdf14ffe031 100644 > > --- a/lib/Kconfig.debug > > +++ b/lib/Kconfig.debug > > @@ -571,6 +571,22 @@ config VMLINUX_MAP > > pieces of code get eliminated with > > CONFIG_LD_DEAD_CODE_DATA_ELIMINATION. > > > > +config BUILTIN_MODULE_RANGES > > + bool "Generate address range information for builtin modules" > > + depends on !LTO_CLANG_FULL > > + depends on !LTO_CLANG_THIN > > + select VMLINUX_MAP > > > I still got > > "WARNING: unmet direct dependencies detected for VMLINUX_MAP" > > > I suggested "depends on VMLINUX_MAP" instead of "select VMLINUX_MAP". > > > > https://lore.kernel.org/linux-kbuild/202405150623.lmS5sVhM-lkp@intel.com/ > > https://lore.kernel.org/linux-kbuild/CAK7LNAST_SbaN9WQRM_k0xE1MUReJvn9AMSg4A1-9b9xotf67w@mail.gmail.com/ Updated. Sorry about that - it should have been "depend on". > > + help > > + When modules are built into the kernel, there will be no module name > > + associated with its symbols in /proc/kallsyms. Tracers may want to > > + identify symbols by module name and symbol name regardless of whether > > + the module is configured as loadable or not. > > + > > + This option generates modules.builtin.ranges in the build tree with > > + offset ranges (per ELF section) for the module(s) they belong to. > > + It also records an anchor symbol to determine the load address of the > > + section. > > + > > config DEBUG_FORCE_WEAK_PER_CPU > > bool "Force weak per-cpu definitions" > > depends on DEBUG_KERNEL > > diff --git a/scripts/Makefile.vmlinux b/scripts/Makefile.vmlinux > > index 49946cb96844..7e21162e9de1 100644 > > --- a/scripts/Makefile.vmlinux > > +++ b/scripts/Makefile.vmlinux > > @@ -33,6 +33,22 @@ targets += vmlinux > > vmlinux: scripts/link-vmlinux.sh vmlinux.o $(KBUILD_LDS) FORCE > > +$(call if_changed_dep,link_vmlinux) > > > > +# module.builtin.ranges > > +# --------------------------------------------------------------------------- > > +ifdef CONFIG_BUILTIN_MODULE_RANGES > > +__default: modules.builtin.ranges > > + > > +quiet_cmd_modules_builtin_ranges = GEN $@ > > + cmd_modules_builtin_ranges = \ > > + $(srctree)/scripts/generate_builtin_ranges.awk $(real-prereqs) > $@ > > + > > +vmlinux.map: vmlinux > > > This should be: > > > vmlinux.map: vmlinux > @: > > > Otherwise, GNU Make would try to find a pattern rule > to update vmlinux.map. Ah, I didn't realize that. Thanks! > > + > > +targets += modules.builtin.ranges > > +modules.builtin.ranges: modules.builtin vmlinux.map vmlinux.o.map FORCE > > + $(call if_changed,modules_builtin_ranges) > > > > Presumably, modules.builtin.ranges should be regenerated when > scripts/generate_builtin_ranges.awk is changed. > > > Maybe, you can do this: > > > quiet_cmd_modules_builtin_ranges = GEN $@ > cmd_modules_builtin_ranges = $(real-prereqs) > $@ > > targets += modules.builtin.ranges > modules.builtin.ranges: $(srctree)/scripts/generate_builtin_ranges.awk \ > modules.builtin vmlinux.map vmlinux.o.map FORCE > $(call if_changed,modules_builtin_ranges) I had thought about that and didn't do it. But I certainly agree that it can be a good idea, so yes, let's do it. It certainly helps while doing more development work or debugging with the generator script. > > +endif > > + > > # Add FORCE to the prequisites of a target to force it to be always rebuilt. > > # --------------------------------------------------------------------------- > > > > diff --git a/scripts/Makefile.vmlinux_o b/scripts/Makefile.vmlinux_o > > index 6de297916ce6..252505505e0e 100644 > > --- a/scripts/Makefile.vmlinux_o > > +++ b/scripts/Makefile.vmlinux_o > > @@ -45,9 +45,12 @@ objtool-args = $(vmlinux-objtool-args-y) --link > > # Link of vmlinux.o used for section mismatch analysis > > # --------------------------------------------------------------------------- > > > > +vmlinux-o-ld-args-$(CONFIG_BUILTIN_MODULE_RANGES) += -Map=$@.map > > + > > quiet_cmd_ld_vmlinux.o = LD $@ > > cmd_ld_vmlinux.o = \ > > $(LD) ${KBUILD_LDFLAGS} -r -o $@ \ > > + $(vmlinux-o-ld-args-y) \ > > $(addprefix -T , $(initcalls-lds)) \ > > --whole-archive vmlinux.a --no-whole-archive \ > > --start-group $(KBUILD_VMLINUX_LIBS) --end-group \ > > diff --git a/scripts/generate_builtin_ranges.awk b/scripts/generate_builtin_ranges.awk > > new file mode 100755 > > index 000000000000..9b647781d5fe > > --- /dev/null > > +++ b/scripts/generate_builtin_ranges.awk > > @@ -0,0 +1,515 @@ > > +#!/usr/bin/gawk -f > > +# SPDX-License-Identifier: GPL-2.0 > > +# generate_builtin_ranges.awk: Generate address range data for builtin modules > > +# Written by Kris Van Hees <kris.van.hees@oracle.com> > > +# > > +# Usage: generate_builtin_ranges.awk modules.builtin vmlinux.map \ > > +# vmlinux.o.map > modules.builtin.ranges > > +# > > + > > +# Return the module name(s) (if any) associated with the given object. > > +# > > +# If we have seen this object before, return information from the cache. > > +# Otherwise, retrieve it from the corresponding .cmd file. > > +# > > +function get_module_info(fn, mod, obj, mfn, s) { > > + if (fn in omod) > > + return omod[fn]; > > + > > + if (match(fn, /\/[^/]+$/) == 0) > > + return ""; > > + > > + obj = fn; > > + mod = ""; > > + mfn = ""; > > + fn = substr(fn, 1, RSTART) "." substr(fn, RSTART + 1) ".cmd"; > > + if (getline s <fn == 1) { > > + if (match(s, /DKBUILD_MODFILE=['"]+[^'"]+/) > 0) { > > + mfn = substr(s, RSTART + 16, RLENGTH - 16); > > + gsub(/['"]/, "", mfn); > > + > > + mod = mfn; > > + gsub(/([^/ ]*\/)+/, "", mod); > > + gsub(/-/, "_", mod); > > + } > > + } > > + close(fn); > > + > > + # A single module (common case) also reflects objects that are not part > > + # of a module. Some of those objects have names that are also a module > > + # name (e.g. core). We check the associated module file name, and if > > + # they do not match, the object is not part of a module. > > + if (mod !~ / /) { > > + if (!(mod in mods)) > > + mod = ""; > > + if (mods[mod] != mfn) > > + mod = ""; > > + } > > + > > + # At this point, mod is a single (valid) module name, or a list of > > + # module names (that do not need validation). > > + omod[obj] = mod; > > + close(fn); > > > Is this "close(fn)" necessary? > I see it a few lines above too. Good catch - not needed. > The code became way simpler since my previous review, but > I think this is still redundant. > > You do not need to check both of modname and its path. > > I attached a patch for code refactoring. Thank you! I didn't think of the approach to keep <dir>/<mod> as the key, but that is indeed simpler. I'll squash your patch into mine. Thank you for the good suggestions. Kris > From fcdc459ce4c7eb84549e45cf06a3a44f90aa3cf9 Mon Sep 17 00:00:00 2001 > From: Masahiro Yamada <masahiroy@kernel.org> > Date: Fri, 16 Aug 2024 23:55:51 +0900 > Subject: [PATCH] fixup modules.builtin.ranges > > Signed-off-by: Masahiro Yamada <masahiroy@kernel.org> > --- > lib/Kconfig.debug | 2 +- > scripts/Makefile.vmlinux | 12 +++++++----- > scripts/generate_builtin_ranges.awk | 25 ++++++++----------------- > 3 files changed, 16 insertions(+), 23 deletions(-) > > diff --git a/lib/Kconfig.debug b/lib/Kconfig.debug > index dcdf14ffe031..f087dc3da321 100644 > --- a/lib/Kconfig.debug > +++ b/lib/Kconfig.debug > @@ -575,7 +575,7 @@ config BUILTIN_MODULE_RANGES > bool "Generate address range information for builtin modules" > depends on !LTO_CLANG_FULL > depends on !LTO_CLANG_THIN > - select VMLINUX_MAP > + depends on VMLINUX_MAP > help > When modules are built into the kernel, there will be no module name > associated with its symbols in /proc/kallsyms. Tracers may want to > diff --git a/scripts/Makefile.vmlinux b/scripts/Makefile.vmlinux > index 7e21162e9de1..7e8b703799c8 100644 > --- a/scripts/Makefile.vmlinux > +++ b/scripts/Makefile.vmlinux > @@ -39,14 +39,16 @@ ifdef CONFIG_BUILTIN_MODULE_RANGES > __default: modules.builtin.ranges > > quiet_cmd_modules_builtin_ranges = GEN $@ > - cmd_modules_builtin_ranges = \ > - $(srctree)/scripts/generate_builtin_ranges.awk $(real-prereqs) > $@ > - > -vmlinux.map: vmlinux > + cmd_modules_builtin_ranges = $(real-prereqs) > $@ > > targets += modules.builtin.ranges > -modules.builtin.ranges: modules.builtin vmlinux.map vmlinux.o.map FORCE > +modules.builtin.ranges: $(srctree)/scripts/generate_builtin_ranges.awk \ > + modules.builtin vmlinux.map vmlinux.o.map FORCE > $(call if_changed,modules_builtin_ranges) > + > +vmlinux.map: vmlinux > + @: > + > endif > > # Add FORCE to the prequisites of a target to force it to be always rebuilt. > diff --git a/scripts/generate_builtin_ranges.awk b/scripts/generate_builtin_ranges.awk > index 9b647781d5fe..865cb7ac4970 100755 > --- a/scripts/generate_builtin_ranges.awk > +++ b/scripts/generate_builtin_ranges.awk > @@ -12,7 +12,7 @@ > # If we have seen this object before, return information from the cache. > # Otherwise, retrieve it from the corresponding .cmd file. > # > -function get_module_info(fn, mod, obj, mfn, s) { > +function get_module_info(fn, mod, obj, s) { > if (fn in omod) > return omod[fn]; > > @@ -21,16 +21,11 @@ function get_module_info(fn, mod, obj, mfn, s) { > > obj = fn; > mod = ""; > - mfn = ""; > fn = substr(fn, 1, RSTART) "." substr(fn, RSTART + 1) ".cmd"; > if (getline s <fn == 1) { > if (match(s, /DKBUILD_MODFILE=['"]+[^'"]+/) > 0) { > - mfn = substr(s, RSTART + 16, RLENGTH - 16); > - gsub(/['"]/, "", mfn); > - > - mod = mfn; > - gsub(/([^/ ]*\/)+/, "", mod); > - gsub(/-/, "_", mod); > + mod = substr(s, RSTART + 16, RLENGTH - 16); > + gsub(/['"]/, "", mod); > } > } > close(fn); > @@ -42,10 +37,11 @@ function get_module_info(fn, mod, obj, mfn, s) { > if (mod !~ / /) { > if (!(mod in mods)) > mod = ""; > - if (mods[mod] != mfn) > - mod = ""; > } > > + gsub(/([^/ ]*\/)+/, "", mod); > + gsub(/-/, "_", mod); > + > # At this point, mod is a single (valid) module name, or a list of > # module names (that do not need validation). > omod[obj] = mod; > @@ -76,18 +72,13 @@ function update_entry(osect, mod, soff, eoff, sect, idx) { > # > # Lines will be like: > # kernel/crypto/lzo-rle.ko > -# and we derive the built-in module name from this as "lzo_rle" and associate > -# it with object name "crypto/lzo-rle". > +# and we record the object name "crypto/lzo-rle". > # > ARGIND == 1 { > sub(/kernel\//, ""); # strip off "kernel/" prefix > sub(/\.ko$/, ""); # strip off .ko suffix > > - mod = $1; > - sub(/([^/]*\/)+/, "", mod); # mod = basename($1) > - gsub(/-/, "_", mod); # Convert - to _ > - > - mods[mod] = $1; > + mods[$1] = 1; > next; > } > > -- > 2.43.0 >
diff --git a/Documentation/process/changes.rst b/Documentation/process/changes.rst index 3fc63f27c226..00f1ed7c59c3 100644 --- a/Documentation/process/changes.rst +++ b/Documentation/process/changes.rst @@ -64,6 +64,7 @@ GNU tar 1.28 tar --version gtags (optional) 6.6.5 gtags --version mkimage (optional) 2017.01 mkimage --version Python (optional) 3.5.x python3 --version +GNU AWK (optional) 5.1.0 gawk --version ====================== =============== ======================================== .. [#f1] Sphinx is needed only to build the Kernel documentation @@ -192,6 +193,12 @@ platforms. The tool is available via the ``u-boot-tools`` package or can be built from the U-Boot source code. See the instructions at https://docs.u-boot.org/en/latest/build/tools.html#building-tools-for-linux +GNU AWK +------- + +GNU AWK is needed if you want kernel builds to generate address range data for +builtin modules (CONFIG_BUILTIN_MODULE_RANGES). + System utilities **************** diff --git a/lib/Kconfig.debug b/lib/Kconfig.debug index a30c03a66172..dcdf14ffe031 100644 --- a/lib/Kconfig.debug +++ b/lib/Kconfig.debug @@ -571,6 +571,22 @@ config VMLINUX_MAP pieces of code get eliminated with CONFIG_LD_DEAD_CODE_DATA_ELIMINATION. +config BUILTIN_MODULE_RANGES + bool "Generate address range information for builtin modules" + depends on !LTO_CLANG_FULL + depends on !LTO_CLANG_THIN + select VMLINUX_MAP + help + When modules are built into the kernel, there will be no module name + associated with its symbols in /proc/kallsyms. Tracers may want to + identify symbols by module name and symbol name regardless of whether + the module is configured as loadable or not. + + This option generates modules.builtin.ranges in the build tree with + offset ranges (per ELF section) for the module(s) they belong to. + It also records an anchor symbol to determine the load address of the + section. + config DEBUG_FORCE_WEAK_PER_CPU bool "Force weak per-cpu definitions" depends on DEBUG_KERNEL diff --git a/scripts/Makefile.vmlinux b/scripts/Makefile.vmlinux index 49946cb96844..7e21162e9de1 100644 --- a/scripts/Makefile.vmlinux +++ b/scripts/Makefile.vmlinux @@ -33,6 +33,22 @@ targets += vmlinux vmlinux: scripts/link-vmlinux.sh vmlinux.o $(KBUILD_LDS) FORCE +$(call if_changed_dep,link_vmlinux) +# module.builtin.ranges +# --------------------------------------------------------------------------- +ifdef CONFIG_BUILTIN_MODULE_RANGES +__default: modules.builtin.ranges + +quiet_cmd_modules_builtin_ranges = GEN $@ + cmd_modules_builtin_ranges = \ + $(srctree)/scripts/generate_builtin_ranges.awk $(real-prereqs) > $@ + +vmlinux.map: vmlinux + +targets += modules.builtin.ranges +modules.builtin.ranges: modules.builtin vmlinux.map vmlinux.o.map FORCE + $(call if_changed,modules_builtin_ranges) +endif + # Add FORCE to the prequisites of a target to force it to be always rebuilt. # --------------------------------------------------------------------------- diff --git a/scripts/Makefile.vmlinux_o b/scripts/Makefile.vmlinux_o index 6de297916ce6..252505505e0e 100644 --- a/scripts/Makefile.vmlinux_o +++ b/scripts/Makefile.vmlinux_o @@ -45,9 +45,12 @@ objtool-args = $(vmlinux-objtool-args-y) --link # Link of vmlinux.o used for section mismatch analysis # --------------------------------------------------------------------------- +vmlinux-o-ld-args-$(CONFIG_BUILTIN_MODULE_RANGES) += -Map=$@.map + quiet_cmd_ld_vmlinux.o = LD $@ cmd_ld_vmlinux.o = \ $(LD) ${KBUILD_LDFLAGS} -r -o $@ \ + $(vmlinux-o-ld-args-y) \ $(addprefix -T , $(initcalls-lds)) \ --whole-archive vmlinux.a --no-whole-archive \ --start-group $(KBUILD_VMLINUX_LIBS) --end-group \ diff --git a/scripts/generate_builtin_ranges.awk b/scripts/generate_builtin_ranges.awk new file mode 100755 index 000000000000..9b647781d5fe --- /dev/null +++ b/scripts/generate_builtin_ranges.awk @@ -0,0 +1,515 @@ +#!/usr/bin/gawk -f +# SPDX-License-Identifier: GPL-2.0 +# generate_builtin_ranges.awk: Generate address range data for builtin modules +# Written by Kris Van Hees <kris.van.hees@oracle.com> +# +# Usage: generate_builtin_ranges.awk modules.builtin vmlinux.map \ +# vmlinux.o.map > modules.builtin.ranges +# + +# Return the module name(s) (if any) associated with the given object. +# +# If we have seen this object before, return information from the cache. +# Otherwise, retrieve it from the corresponding .cmd file. +# +function get_module_info(fn, mod, obj, mfn, s) { + if (fn in omod) + return omod[fn]; + + if (match(fn, /\/[^/]+$/) == 0) + return ""; + + obj = fn; + mod = ""; + mfn = ""; + fn = substr(fn, 1, RSTART) "." substr(fn, RSTART + 1) ".cmd"; + if (getline s <fn == 1) { + if (match(s, /DKBUILD_MODFILE=['"]+[^'"]+/) > 0) { + mfn = substr(s, RSTART + 16, RLENGTH - 16); + gsub(/['"]/, "", mfn); + + mod = mfn; + gsub(/([^/ ]*\/)+/, "", mod); + gsub(/-/, "_", mod); + } + } + close(fn); + + # A single module (common case) also reflects objects that are not part + # of a module. Some of those objects have names that are also a module + # name (e.g. core). We check the associated module file name, and if + # they do not match, the object is not part of a module. + if (mod !~ / /) { + if (!(mod in mods)) + mod = ""; + if (mods[mod] != mfn) + mod = ""; + } + + # At this point, mod is a single (valid) module name, or a list of + # module names (that do not need validation). + omod[obj] = mod; + close(fn); + + return mod; +} + +# Update the ranges entry for the given module 'mod' in section 'osect'. +# +# We use a modified absolute start address (soff + base) as index because we +# may need to insert an anchor record later that must be at the start of the +# section data, and the first module may very well start at the same address. +# So, we use (addr << 1) + 1 to allow a possible anchor record to be placed at +# (addr << 1). This is safe because the index is only used to sort the entries +# before writing them out. +# +function update_entry(osect, mod, soff, eoff, sect, idx) { + sect = sect_in[osect]; + idx = (soff + sect_base[osect]) * 2 + 1; + entries[idx] = sprintf("%s %08x-%08x %s", sect, soff, eoff, mod); + count[sect]++; +} + +# (1) Build a lookup map of built-in module names. +# +# The first file argument is used as input (modules.builtin). +# +# Lines will be like: +# kernel/crypto/lzo-rle.ko +# and we derive the built-in module name from this as "lzo_rle" and associate +# it with object name "crypto/lzo-rle". +# +ARGIND == 1 { + sub(/kernel\//, ""); # strip off "kernel/" prefix + sub(/\.ko$/, ""); # strip off .ko suffix + + mod = $1; + sub(/([^/]*\/)+/, "", mod); # mod = basename($1) + gsub(/-/, "_", mod); # Convert - to _ + + mods[mod] = $1; + next; +} + +# (2) Collect address information for each section. +# +# The second file argument is used as input (vmlinux.map). +# +# We collect the base address of the section in order to convert all addresses +# in the section into offset values. +# +# We collect the address of the anchor (or first symbol in the section if there +# is no explicit anchor) to allow users of the range data to calculate address +# ranges based on the actual load address of the section in the running kernel. +# +# We collect the start address of any sub-section (section included in the top +# level section being processed). This is needed when the final linking was +# done using vmlinux.a because then the list of objects contained in each +# section is to be obtained from vmlinux.o.map. The offset of the sub-section +# is recorded here, to be used as an addend when processing vmlinux.o.map +# later. +# + +# Both GNU ld and LLVM lld linker map format are supported by converting LLVM +# lld linker map records into equivalent GNU ld linker map records. +# +# The first record of the vmlinux.map file provides enough information to know +# which format we are dealing with. +# +ARGIND == 2 && FNR == 1 && NF == 7 && $1 == "VMA" && $7 == "Symbol" { + map_is_lld = 1; + if (dbg) + printf "NOTE: %s uses LLVM lld linker map format\n", FILENAME >"/dev/stderr"; + next; +} + +# (LLD) Convert a section record fronm lld format to ld format. +# +# lld: ffffffff82c00000 2c00000 2493c0 8192 .data +# -> +# ld: .data 0xffffffff82c00000 0x2493c0 load address 0x0000000002c00000 +# +ARGIND == 2 && map_is_lld && NF == 5 && /[0-9] [^ ]+$/ { + $0 = $5 " 0x"$1 " 0x"$3 " load address 0x"$2; +} + +# (LLD) Convert an anchor record from lld format to ld format. +# +# lld: ffffffff81000000 1000000 0 1 _text = . +# -> +# ld: 0xffffffff81000000 _text = . +# +ARGIND == 2 && map_is_lld && !anchor && NF == 7 && raw_addr == "0x"$1 && $6 == "=" && $7 == "." { + $0 = " 0x"$1 " " $5 " = ."; +} + +# (LLD) Convert an object record from lld format to ld format. +# +# lld: 11480 11480 1f07 16 vmlinux.a(arch/x86/events/amd/uncore.o):(.text) +# -> +# ld: .text 0x0000000000011480 0x1f07 arch/x86/events/amd/uncore.o +# +ARGIND == 2 && map_is_lld && NF == 5 && $5 ~ /:\(/ { + gsub(/\)/, ""); + sub(/ vmlinux\.a\(/, " "); + sub(/:\(/, " "); + $0 = " "$6 " 0x"$1 " 0x"$3 " " $5; +} + +# (LLD) Convert a symbol record from lld format to ld format. +# +# We only care about these while processing a section for which no anchor has +# been determined yet. +# +# lld: ffffffff82a859a4 2a859a4 0 1 btf_ksym_iter_id +# -> +# ld: 0xffffffff82a859a4 btf_ksym_iter_id +# +ARGIND == 2 && map_is_lld && sect && !anchor && NF == 5 && $5 ~ /^[_A-Za-z][_A-Za-z0-9]*$/ { + $0 = " 0x"$1 " " $5; +} + +# (LLD) We do not need any other ldd linker map records. +# +ARGIND == 2 && map_is_lld && /^[0-9a-f]{16} / { + next; +} + +# (LD) Section records with just the section name at the start of the line +# need to have the next line pulled in to determine whether it is a +# loadable section. If it is, the next line will contains a hex value +# as first and second items. +# +ARGIND == 2 && !map_is_lld && NF == 1 && /^[^ ]/ { + s = $0; + getline; + if ($1 !~ /^0x/ || $2 !~ /^0x/) + next; + + $0 = s " " $0; +} + +# (LD) Object records with just the section name denote records with a long +# section name for which the remainder of the record can be found on the +# next line. +# +# (This is also needed for vmlinux.o.map, when used.) +# +ARGIND >= 2 && !map_is_lld && NF == 1 && /^ [^ \*]/ { + s = $0; + getline; + $0 = s " " $0; +} + +# Beginning a new section - done with the previous one (if any). +# +ARGIND == 2 && /^[^ ]/ { + sect = 0; +} + +# Process a loadable section (we only care about .-sections). +# +# Record the section name and its base address. +# We also record the raw (non-stripped) address of the section because it can +# be used to identify an anchor record. +# +# Note: +# Since some AWK implementations cannot handle large integers, we strip off the +# first 4 hex digits from the address. This is safe because the kernel space +# is not large enough for addresses to extend into those digits. The portion +# to strip off is stored in addr_prefix as a regexp, so further clauses can +# perform a simple substitution to do the address stripping. +# +ARGIND == 2 && /^\./ { + # Explicitly ignore a few sections that are not relevant here. + if ($1 ~ /^\.orc_/ || $1 ~ /_sites$/ || $1 ~ /\.percpu/) + next; + + # Sections with a 0-address can be ignored as well. + if ($2 ~ /^0x0+$/) + next; + + raw_addr = $2; + addr_prefix = "^" substr($2, 1, 6); + base = $2; + sub(addr_prefix, "0x", base); + base = strtonum(base); + sect = $1; + anchor = 0; + sect_base[sect] = base; + sect_size[sect] = strtonum($3); + + if (dbg) + printf "[%s] BASE %016x\n", sect, base >"/dev/stderr"; + + next; +} + +# If we are not in a section we care about, we ignore the record. +# +ARGIND == 2 && !sect { + next; +} + +# Record the first anchor symbol for the current section. +# +# An anchor record for the section bears the same raw address as the section +# record. +# +ARGIND == 2 && !anchor && NF == 4 && raw_addr == $1 && $3 == "=" && $4 == "." { + anchor = sprintf("%s %08x-%08x = %s", sect, 0, 0, $2); + sect_anchor[sect] = anchor; + + if (dbg) + printf "[%s] ANCHOR %016x = %s (.)\n", sect, 0, $2 >"/dev/stderr"; + + next; +} + +# If no anchor record was found for the current section, use the first symbol +# in the section as anchor. +# +ARGIND == 2 && !anchor && NF == 2 && $1 ~ /^0x/ && $2 !~ /^0x/ { + addr = $1; + sub(addr_prefix, "0x", addr); + addr = strtonum(addr) - base; + anchor = sprintf("%s %08x-%08x = %s", sect, addr, addr, $2); + sect_anchor[sect] = anchor; + + if (dbg) + printf "[%s] ANCHOR %016x = %s\n", sect, addr, $2 >"/dev/stderr"; + + next; +} + +# The first occurence of a section name in an object record establishes the +# addend (often 0) for that section. This information is needed to handle +# sections that get combined in the final linking of vmlinux (e.g. .head.text +# getting included at the start of .text). +# +# If the section does not have a base yet, use the base of the encapsulating +# section. +# +ARGIND == 2 && sect && NF == 4 && /^ [^ \*]/ && !($1 in sect_addend) { + if (!($1 in sect_base)) { + sect_base[$1] = base; + + if (dbg) + printf "[%s] BASE %016x\n", $1, base >"/dev/stderr"; + } + + addr = $2; + sub(addr_prefix, "0x", addr); + addr = strtonum(addr); + sect_addend[$1] = addr - sect_base[$1]; + sect_in[$1] = sect; + + if (dbg) + printf "[%s] ADDEND %016x - %016x = %016x\n", $1, addr, base, sect_addend[$1] >"/dev/stderr"; + + # If the object is vmlinux.o then we will need vmlinux.o.map to get the + # actual offsets of objects. + if ($4 == "vmlinux.o") + need_o_map = 1; +} + +# (3) Collect offset ranges (relative to the section base address) for built-in +# modules. +# +# If the final link was done using the actual objects, vmlinux.map contains all +# the information we need (see section (3a)). +# If linking was done using vmlinux.a as intermediary, we will need to process +# vmlinux.o.map (see section (3b)). + +# (3a) Determine offset range info using vmlinux.map. +# +# Since we are already processing vmlinux.map, the top level section that is +# being processed is already known. If we do not have a base address for it, +# we do not need to process records for it. +# +# Given the object name, we determine the module(s) (if any) that the current +# object is associated with. +# +# If we were already processing objects for a (list of) module(s): +# - If the current object belongs to the same module(s), update the range data +# to include the current object. +# - Otherwise, ensure that the end offset of the range is valid. +# +# If the current object does not belong to a built-in module, ignore it. +# +# If it does, we add a new built-in module offset range record. +# +ARGIND == 2 && !need_o_map && /^ [^ ]/ && NF == 4 && $3 != "0x0" { + if (!(sect in sect_base)) + next; + + # Turn the address into an offset from the section base. + soff = $2; + sub(addr_prefix, "0x", soff); + soff = strtonum(soff) - sect_base[sect]; + eoff = soff + strtonum($3); + + # Determine which (if any) built-in modules the object belongs to. + mod = get_module_info($4); + + # If we are processing a built-in module: + # - If the current object is within the same module, we update its + # entry by extending the range and move on + # - Otherwise: + # + If we are still processing within the same main section, we + # validate the end offset against the start offset of the + # current object (e.g. .rodata.str1.[18] objects are often + # listed with an incorrect size in the linker map) + # + Otherwise, we validate the end offset against the section + # size + if (mod_name) { + if (mod == mod_name) { + mod_eoff = eoff; + update_entry(mod_sect, mod_name, mod_soff, eoff); + + next; + } else if (sect == sect_in[mod_sect]) { + if (mod_eoff > soff) + update_entry(mod_sect, mod_name, mod_soff, soff); + } else { + v = sect_size[sect_in[mod_sect]]; + if (mod_eoff > v) + update_entry(mod_sect, mod_name, mod_soff, v); + } + } + + mod_name = mod; + + # If we encountered an object that is not part of a built-in module, we + # do not need to record any data. + if (!mod) + next; + + # At this point, we encountered the start of a new built-in module. + mod_name = mod; + mod_soff = soff; + mod_eoff = eoff; + mod_sect = $1; + update_entry($1, mod, soff, mod_eoff); + + next; +} + +# If we do not need to parse the vmlinux.o.map file, we are done. +# +ARGIND == 3 && !need_o_map { + if (dbg) + printf "Note: %s is not needed.\n", FILENAME >"/dev/stderr"; + exit; +} + +# (3) Collect offset ranges (relative to the section base address) for built-in +# modules. +# + +# (LLD) Convert an object record from lld format to ld format. +# +ARGIND == 3 && map_is_lld && NF == 5 && $5 ~ /:\(/ { + gsub(/\)/, ""); + sub(/:\(/, " "); + + sect = $6; + if (!(sect in sect_addend)) + next; + + sub(/ vmlinux\.a\(/, " "); + $0 = " "sect " 0x"$1 " 0x"$3 " " $5; +} + +# (3b) Determine offset range info using vmlinux.o.map. +# +# If we do not know an addend for the object's section, we are interested in +# anything within that section. +# +# Determine the top-level section that the object's section was included in +# during the final link. This is the section name offset range data will be +# associated with for this object. +# +# The remainder of the processing of the current object record follows the +# procedure outlined in (3a). +# +ARGIND == 3 && /^ [^ ]/ && NF == 4 && $3 != "0x0" { + osect = $1; + if (!(osect in sect_addend)) + next; + + # We need to work with the main section. + sect = sect_in[osect]; + + # Turn the address into an offset from the section base. + soff = $2; + sub(addr_prefix, "0x", soff); + soff = strtonum(soff) + sect_addend[osect]; + eoff = soff + strtonum($3); + + # Determine which (if any) built-in modules the object belongs to. + mod = get_module_info($4); + + # If we are processing a built-in module: + # - If the current object is within the same module, we update its + # entry by extending the range and move on + # - Otherwise: + # + If we are still processing within the same main section, we + # validate the end offset against the start offset of the + # current object (e.g. .rodata.str1.[18] objects are often + # listed with an incorrect size in the linker map) + # + Otherwise, we validate the end offset against the section + # size + if (mod_name) { + if (mod == mod_name) { + mod_eoff = eoff; + update_entry(mod_sect, mod_name, mod_soff, eoff); + + next; + } else if (sect == sect_in[mod_sect]) { + if (mod_eoff > soff) + update_entry(mod_sect, mod_name, mod_soff, soff); + } else { + v = sect_size[sect_in[mod_sect]]; + if (mod_eoff > v) + update_entry(mod_sect, mod_name, mod_soff, v); + } + } + + mod_name = mod; + + # If we encountered an object that is not part of a built-in module, we + # do not need to record any data. + if (!mod) + next; + + # At this point, we encountered the start of a new built-in module. + mod_name = mod; + mod_soff = soff; + mod_eoff = eoff; + mod_sect = osect; + update_entry(osect, mod, soff, mod_eoff); + + next; +} + +# (4) Generate the output. +# +# Anchor records are added for each section that contains offset range data +# records. They are added at an adjusted section base address (base << 1) to +# ensure they come first in the second records (see update_entry() above for +# more informtion). +# +# All entries are sorted by (adjusted) address to ensure that the output can be +# parsed in strict ascending address order. +# +END { + for (sect in count) { + if (sect in sect_anchor) + entries[sect_base[sect] * 2] = sect_anchor[sect]; + } + + n = asorti(entries, indices); + for (i = 1; i <= n; i++) + print entries[indices[i]]; +}