509 lines
15 KiB
Awk
509 lines
15 KiB
Awk
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#!/usr/bin/gawk -f
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# SPDX-License-Identifier: GPL-2.0
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# generate_builtin_ranges.awk: Generate address range data for builtin modules
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# Written by Kris Van Hees <kris.van.hees@oracle.com>
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#
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# Usage: generate_builtin_ranges.awk modules.builtin vmlinux.map \
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# vmlinux.o.map > modules.builtin.ranges
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#
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# Return the module name(s) (if any) associated with the given object.
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#
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# If we have seen this object before, return information from the cache.
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# Otherwise, retrieve it from the corresponding .cmd file.
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#
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function get_module_info(fn, mod, obj, s) {
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if (fn in omod)
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return omod[fn];
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if (match(fn, /\/[^/]+$/) == 0)
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return "";
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obj = fn;
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mod = "";
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fn = substr(fn, 1, RSTART) "." substr(fn, RSTART + 1) ".cmd";
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if (getline s <fn == 1) {
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if (match(s, /DKBUILD_MODFILE=['"]+[^'"]+/) > 0) {
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mod = substr(s, RSTART + 16, RLENGTH - 16);
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gsub(/['"]/, "", mod);
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} else if (match(s, /RUST_MODFILE=[^ ]+/) > 0)
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mod = substr(s, RSTART + 13, RLENGTH - 13);
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}
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close(fn);
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# A single module (common case) also reflects objects that are not part
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# of a module. Some of those objects have names that are also a module
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# name (e.g. core). We check the associated module file name, and if
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# they do not match, the object is not part of a module.
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if (mod !~ / /) {
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if (!(mod in mods))
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mod = "";
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}
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gsub(/([^/ ]*\/)+/, "", mod);
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gsub(/-/, "_", mod);
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# At this point, mod is a single (valid) module name, or a list of
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# module names (that do not need validation).
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omod[obj] = mod;
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return mod;
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}
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# Update the ranges entry for the given module 'mod' in section 'osect'.
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#
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# We use a modified absolute start address (soff + base) as index because we
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# may need to insert an anchor record later that must be at the start of the
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# section data, and the first module may very well start at the same address.
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# So, we use (addr << 1) + 1 to allow a possible anchor record to be placed at
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# (addr << 1). This is safe because the index is only used to sort the entries
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# before writing them out.
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#
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function update_entry(osect, mod, soff, eoff, sect, idx) {
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sect = sect_in[osect];
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idx = sprintf("%016x", (soff + sect_base[osect]) * 2 + 1);
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entries[idx] = sprintf("%s %08x-%08x %s", sect, soff, eoff, mod);
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count[sect]++;
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}
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# (1) Build a lookup map of built-in module names.
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#
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# The first file argument is used as input (modules.builtin).
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#
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# Lines will be like:
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# kernel/crypto/lzo-rle.ko
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# and we record the object name "crypto/lzo-rle".
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#
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ARGIND == 1 {
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sub(/kernel\//, ""); # strip off "kernel/" prefix
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sub(/\.ko$/, ""); # strip off .ko suffix
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mods[$1] = 1;
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next;
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}
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# (2) Collect address information for each section.
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#
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# The second file argument is used as input (vmlinux.map).
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#
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# We collect the base address of the section in order to convert all addresses
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# in the section into offset values.
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#
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# We collect the address of the anchor (or first symbol in the section if there
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# is no explicit anchor) to allow users of the range data to calculate address
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# ranges based on the actual load address of the section in the running kernel.
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#
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# We collect the start address of any sub-section (section included in the top
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# level section being processed). This is needed when the final linking was
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# done using vmlinux.a because then the list of objects contained in each
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# section is to be obtained from vmlinux.o.map. The offset of the sub-section
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# is recorded here, to be used as an addend when processing vmlinux.o.map
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# later.
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#
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# Both GNU ld and LLVM lld linker map format are supported by converting LLVM
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# lld linker map records into equivalent GNU ld linker map records.
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#
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# The first record of the vmlinux.map file provides enough information to know
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# which format we are dealing with.
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#
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ARGIND == 2 && FNR == 1 && NF == 7 && $1 == "VMA" && $7 == "Symbol" {
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map_is_lld = 1;
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if (dbg)
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printf "NOTE: %s uses LLVM lld linker map format\n", FILENAME >"/dev/stderr";
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next;
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}
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# (LLD) Convert a section record fronm lld format to ld format.
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#
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# lld: ffffffff82c00000 2c00000 2493c0 8192 .data
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# ->
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# ld: .data 0xffffffff82c00000 0x2493c0 load address 0x0000000002c00000
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#
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ARGIND == 2 && map_is_lld && NF == 5 && /[0-9] [^ ]+$/ {
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$0 = $5 " 0x"$1 " 0x"$3 " load address 0x"$2;
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}
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# (LLD) Convert an anchor record from lld format to ld format.
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#
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# lld: ffffffff81000000 1000000 0 1 _text = .
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# ->
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# ld: 0xffffffff81000000 _text = .
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#
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ARGIND == 2 && map_is_lld && !anchor && NF == 7 && raw_addr == "0x"$1 && $6 == "=" && $7 == "." {
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$0 = " 0x"$1 " " $5 " = .";
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}
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# (LLD) Convert an object record from lld format to ld format.
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#
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# lld: 11480 11480 1f07 16 vmlinux.a(arch/x86/events/amd/uncore.o):(.text)
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# ->
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# ld: .text 0x0000000000011480 0x1f07 arch/x86/events/amd/uncore.o
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#
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ARGIND == 2 && map_is_lld && NF == 5 && $5 ~ /:\(/ {
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gsub(/\)/, "");
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sub(/ vmlinux\.a\(/, " ");
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sub(/:\(/, " ");
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$0 = " "$6 " 0x"$1 " 0x"$3 " " $5;
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}
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# (LLD) Convert a symbol record from lld format to ld format.
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#
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# We only care about these while processing a section for which no anchor has
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# been determined yet.
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#
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# lld: ffffffff82a859a4 2a859a4 0 1 btf_ksym_iter_id
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# ->
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# ld: 0xffffffff82a859a4 btf_ksym_iter_id
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#
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ARGIND == 2 && map_is_lld && sect && !anchor && NF == 5 && $5 ~ /^[_A-Za-z][_A-Za-z0-9]*$/ {
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$0 = " 0x"$1 " " $5;
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}
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# (LLD) We do not need any other ldd linker map records.
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#
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ARGIND == 2 && map_is_lld && /^[0-9a-f]{16} / {
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next;
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}
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# (LD) Section records with just the section name at the start of the line
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# need to have the next line pulled in to determine whether it is a
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# loadable section. If it is, the next line will contains a hex value
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# as first and second items.
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#
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ARGIND == 2 && !map_is_lld && NF == 1 && /^[^ ]/ {
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s = $0;
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getline;
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if ($1 !~ /^0x/ || $2 !~ /^0x/)
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next;
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$0 = s " " $0;
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}
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# (LD) Object records with just the section name denote records with a long
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# section name for which the remainder of the record can be found on the
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# next line.
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#
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# (This is also needed for vmlinux.o.map, when used.)
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#
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ARGIND >= 2 && !map_is_lld && NF == 1 && /^ [^ \*]/ {
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s = $0;
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getline;
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$0 = s " " $0;
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}
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# Beginning a new section - done with the previous one (if any).
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#
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ARGIND == 2 && /^[^ ]/ {
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sect = 0;
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}
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# Process a loadable section (we only care about .-sections).
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#
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# Record the section name and its base address.
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# We also record the raw (non-stripped) address of the section because it can
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# be used to identify an anchor record.
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#
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# Note:
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# Since some AWK implementations cannot handle large integers, we strip off the
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# first 4 hex digits from the address. This is safe because the kernel space
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# is not large enough for addresses to extend into those digits. The portion
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# to strip off is stored in addr_prefix as a regexp, so further clauses can
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# perform a simple substitution to do the address stripping.
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#
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ARGIND == 2 && /^\./ {
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# Explicitly ignore a few sections that are not relevant here.
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if ($1 ~ /^\.orc_/ || $1 ~ /_sites$/ || $1 ~ /\.percpu/)
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next;
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# Sections with a 0-address can be ignored as well.
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if ($2 ~ /^0x0+$/)
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next;
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raw_addr = $2;
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addr_prefix = "^" substr($2, 1, 6);
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base = $2;
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sub(addr_prefix, "0x", base);
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base = strtonum(base);
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sect = $1;
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anchor = 0;
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sect_base[sect] = base;
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sect_size[sect] = strtonum($3);
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if (dbg)
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printf "[%s] BASE %016x\n", sect, base >"/dev/stderr";
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next;
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}
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# If we are not in a section we care about, we ignore the record.
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#
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ARGIND == 2 && !sect {
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next;
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}
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# Record the first anchor symbol for the current section.
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#
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# An anchor record for the section bears the same raw address as the section
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# record.
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#
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ARGIND == 2 && !anchor && NF == 4 && raw_addr == $1 && $3 == "=" && $4 == "." {
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anchor = sprintf("%s %08x-%08x = %s", sect, 0, 0, $2);
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sect_anchor[sect] = anchor;
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if (dbg)
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printf "[%s] ANCHOR %016x = %s (.)\n", sect, 0, $2 >"/dev/stderr";
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next;
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}
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# If no anchor record was found for the current section, use the first symbol
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# in the section as anchor.
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#
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ARGIND == 2 && !anchor && NF == 2 && $1 ~ /^0x/ && $2 !~ /^0x/ {
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addr = $1;
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sub(addr_prefix, "0x", addr);
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addr = strtonum(addr) - base;
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anchor = sprintf("%s %08x-%08x = %s", sect, addr, addr, $2);
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sect_anchor[sect] = anchor;
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if (dbg)
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printf "[%s] ANCHOR %016x = %s\n", sect, addr, $2 >"/dev/stderr";
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next;
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}
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# The first occurrence of a section name in an object record establishes the
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# addend (often 0) for that section. This information is needed to handle
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# sections that get combined in the final linking of vmlinux (e.g. .head.text
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# getting included at the start of .text).
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#
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# If the section does not have a base yet, use the base of the encapsulating
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# section.
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#
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ARGIND == 2 && sect && NF == 4 && /^ [^ \*]/ && !($1 in sect_addend) {
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if (!($1 in sect_base)) {
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sect_base[$1] = base;
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if (dbg)
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printf "[%s] BASE %016x\n", $1, base >"/dev/stderr";
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}
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addr = $2;
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sub(addr_prefix, "0x", addr);
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addr = strtonum(addr);
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sect_addend[$1] = addr - sect_base[$1];
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sect_in[$1] = sect;
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if (dbg)
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printf "[%s] ADDEND %016x - %016x = %016x\n", $1, addr, base, sect_addend[$1] >"/dev/stderr";
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# If the object is vmlinux.o then we will need vmlinux.o.map to get the
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# actual offsets of objects.
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if ($4 == "vmlinux.o")
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need_o_map = 1;
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}
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# (3) Collect offset ranges (relative to the section base address) for built-in
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# modules.
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#
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# If the final link was done using the actual objects, vmlinux.map contains all
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# the information we need (see section (3a)).
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# If linking was done using vmlinux.a as intermediary, we will need to process
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# vmlinux.o.map (see section (3b)).
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# (3a) Determine offset range info using vmlinux.map.
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#
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# Since we are already processing vmlinux.map, the top level section that is
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# being processed is already known. If we do not have a base address for it,
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# we do not need to process records for it.
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#
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# Given the object name, we determine the module(s) (if any) that the current
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# object is associated with.
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#
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# If we were already processing objects for a (list of) module(s):
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# - If the current object belongs to the same module(s), update the range data
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# to include the current object.
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# - Otherwise, ensure that the end offset of the range is valid.
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#
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# If the current object does not belong to a built-in module, ignore it.
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#
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# If it does, we add a new built-in module offset range record.
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#
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ARGIND == 2 && !need_o_map && /^ [^ ]/ && NF == 4 && $3 != "0x0" {
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if (!(sect in sect_base))
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next;
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# Turn the address into an offset from the section base.
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soff = $2;
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sub(addr_prefix, "0x", soff);
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soff = strtonum(soff) - sect_base[sect];
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eoff = soff + strtonum($3);
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# Determine which (if any) built-in modules the object belongs to.
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mod = get_module_info($4);
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# If we are processing a built-in module:
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# - If the current object is within the same module, we update its
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# entry by extending the range and move on
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# - Otherwise:
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# + If we are still processing within the same main section, we
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# validate the end offset against the start offset of the
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# current object (e.g. .rodata.str1.[18] objects are often
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# listed with an incorrect size in the linker map)
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# + Otherwise, we validate the end offset against the section
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# size
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if (mod_name) {
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if (mod == mod_name) {
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mod_eoff = eoff;
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update_entry(mod_sect, mod_name, mod_soff, eoff);
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next;
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} else if (sect == sect_in[mod_sect]) {
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if (mod_eoff > soff)
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update_entry(mod_sect, mod_name, mod_soff, soff);
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} else {
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v = sect_size[sect_in[mod_sect]];
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if (mod_eoff > v)
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update_entry(mod_sect, mod_name, mod_soff, v);
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}
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}
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mod_name = mod;
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# If we encountered an object that is not part of a built-in module, we
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# do not need to record any data.
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if (!mod)
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next;
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# At this point, we encountered the start of a new built-in module.
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mod_name = mod;
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mod_soff = soff;
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mod_eoff = eoff;
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mod_sect = $1;
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update_entry($1, mod, soff, mod_eoff);
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next;
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}
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# If we do not need to parse the vmlinux.o.map file, we are done.
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#
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ARGIND == 3 && !need_o_map {
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if (dbg)
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printf "Note: %s is not needed.\n", FILENAME >"/dev/stderr";
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exit;
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}
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# (3) Collect offset ranges (relative to the section base address) for built-in
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# modules.
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#
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# (LLD) Convert an object record from lld format to ld format.
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#
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ARGIND == 3 && map_is_lld && NF == 5 && $5 ~ /:\(/ {
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gsub(/\)/, "");
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sub(/:\(/, " ");
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sect = $6;
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||
|
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]];
|
||
|
}
|