linux/scripts/generate_builtin_ranges.awk
Kris Van Hees 5f5e734432 kbuild: generate offset range data for builtin modules
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

The generated data will look like:

.text 00000000-00000000 = _text
.text 0000baf0-0000cb10 amd_uncore
.text 0009bd10-0009c8e0 iosf_mbi
...
.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
...
.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 straight-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>
Tested-by: Sam James <sam@gentoo.org>
Reviewed-by: Sami Tolvanen <samitolvanen@google.com>
Tested-by: Sami Tolvanen <samitolvanen@google.com>
Signed-off-by: Masahiro Yamada <masahiroy@kernel.org>
2024-09-20 09:21:43 +09:00

509 lines
15 KiB
Awk
Executable File

#!/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, s) {
if (fn in omod)
return omod[fn];
if (match(fn, /\/[^/]+$/) == 0)
return "";
obj = fn;
mod = "";
fn = substr(fn, 1, RSTART) "." substr(fn, RSTART + 1) ".cmd";
if (getline s <fn == 1) {
if (match(s, /DKBUILD_MODFILE=['"]+[^'"]+/) > 0) {
mod = substr(s, RSTART + 16, RLENGTH - 16);
gsub(/['"]/, "", mod);
} else if (match(s, /RUST_MODFILE=[^ ]+/) > 0)
mod = substr(s, RSTART + 13, RLENGTH - 13);
}
close(fn);
# A single module (common case) also reflects objects that are not part
# of a module. Some of those objects have names that are also a module
# name (e.g. core). We check the associated module file name, and if
# they do not match, the object is not part of a module.
if (mod !~ / /) {
if (!(mod in mods))
mod = "";
}
gsub(/([^/ ]*\/)+/, "", mod);
gsub(/-/, "_", mod);
# At this point, mod is a single (valid) module name, or a list of
# module names (that do not need validation).
omod[obj] = mod;
return mod;
}
# Update the ranges entry for the given module 'mod' in section 'osect'.
#
# We use a modified absolute start address (soff + base) as index because we
# may need to insert an anchor record later that must be at the start of the
# section data, and the first module may very well start at the same address.
# So, we use (addr << 1) + 1 to allow a possible anchor record to be placed at
# (addr << 1). This is safe because the index is only used to sort the entries
# before writing them out.
#
function update_entry(osect, mod, soff, eoff, sect, idx) {
sect = sect_in[osect];
idx = sprintf("%016x", (soff + sect_base[osect]) * 2 + 1);
entries[idx] = sprintf("%s %08x-%08x %s", sect, soff, eoff, mod);
count[sect]++;
}
# (1) Build a lookup map of built-in module names.
#
# The first file argument is used as input (modules.builtin).
#
# Lines will be like:
# kernel/crypto/lzo-rle.ko
# and we record the object name "crypto/lzo-rle".
#
ARGIND == 1 {
sub(/kernel\//, ""); # strip off "kernel/" prefix
sub(/\.ko$/, ""); # strip off .ko suffix
mods[$1] = 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 occurrence 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 information).
#
# 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) {
idx = sprintf("%016x", sect_base[sect] * 2);
entries[idx] = sect_anchor[sect];
}
}
n = asorti(entries, indices);
for (i = 1; i <= n; i++)
print entries[indices[i]];
}