#!/usr/perl5/bin/perl -w # # CDDL HEADER START # # The contents of this file are subject to the terms of the # Common Development and Distribution License (the "License"). # You may not use this file except in compliance with the License. # # You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE # or http://www.opensolaris.org/os/licensing. # See the License for the specific language governing permissions # and limitations under the License. # # When distributing Covered Code, include this CDDL HEADER in each # file and include the License file at usr/src/OPENSOLARIS.LICENSE. # If applicable, add the following below this CDDL HEADER, with the # fields enclosed by brackets "[]" replaced with your own identifying # information: Portions Copyright [yyyy] [name of copyright owner] # # CDDL HEADER END # # # Copyright (c) 1999, 2010, Oracle and/or its affiliates. All rights reserved. # Copyright 2020 Oxide Computer Company # # # Check ELF information. # # This script descends a directory hierarchy inspecting ELF objects. The # general theme is to verify that common Makefile rules have been used to # build these objects. Typical failures occur when Makefile rules are # re-invented rather than being inherited from "cmd/lib" Makefiles. # # As always, a number of components don't follow the rules, and these are # excluded to reduce this scripts output. # # By default any file that has conditions that should be reported is first # listed and then each condition follows. The -o (one-line) option produces a # more terse output which is better for sorting/diffing with "nightly". # # NOTE: missing dependencies, symbols or versions are reported by running the # file through ldd(1). As objects within a proto area are built to exist in a # base system, standard use of ldd(1) will bind any objects to dependencies # that exist in the base system. It is frequently the case that newer objects # exist in the proto area that are required to satisfy other objects # dependencies, and without using these newer objects an ldd(1) will produce # misleading error messages. To compensate for this, the -D/-d options, or the # existence of the CODEMSG_WS/ROOT environment variables, cause the creation of # alternative dependency mappings via crle(1) configuration files that establish # any proto shared objects as alternatives to their base system location. Thus # ldd(1) can be executed against these configuration files so that objects in a # proto area bind to their dependencies in the same proto area. # Define all global variables (required for strict) use vars qw($Prog $Env $Ena64 $Tmpdir); use vars qw($LddNoU $Conf32 $Conf64); use vars qw(%opt); use vars qw($ErrFH $ErrTtl $InfoFH $InfoTtl $OutCnt1 $OutCnt2); # An exception file is used to specify regular expressions to match # objects. These directives specify special attributes of the object. # The regular expressions are read from the file and compiled into the # regular expression variables. # # The name of each regular expression variable is of the form # # $EXRE_xxx # # where xxx is the name of the exception in lower case. For example, # the regular expression variable for EXEC_STACK is $EXRE_exec_stack. # # onbld_elfmod::LoadExceptionsToEXRE() depends on this naming convention # to initialize the regular expression variables, and to detect invalid # exception names. # # If a given exception is not used in the exception file, its regular # expression variable will be undefined. Users of these variables must # test the variable with defined() prior to use: # # defined($EXRE_exec_stack) && ($foo =~ $EXRE_exec_stack) # # or if the test is to make sure the item is not specified: # # !defined($EXRE_exec_stack) || ($foo !~ $EXRE_exec_stack) # # ---- # # The exceptions are: # # EXEC_DATA # Objects that are not required to have non-executable writable # data segments. # # EXEC_STACK # Objects that are not required to have a non-executable stack # # FORBIDDEN_DEP # Objects allowed to link to 'forbidden' objects # # FORBIDDEN # Objects to which nobody not excepted with FORBIDDEN_DEP may link # # NOT_KMOD # Objects that we think should be linked with -ztype=kmod but are # allowed to not be. # # NOCRLEALT # Objects that should be skipped by AltObjectConfig() when building # the crle script that maps objects to the proto area. # # NODIRECT # Objects that are not required to use direct bindings # # NOSYMSORT # Objects we should not check for duplicate addresses in # the symbol sort sections. # # OLDDEP # Objects that are no longer needed because their functionalty # has migrated elsewhere. These are usually pure filters that # point at libc. # # SKIP # Files and directories that should be excluded from analysis. # # STAB # Objects that are allowed to contain stab debugging sections # # TEXTREL # Object for which relocations are allowed to the text segment # # UNDEF_REF # Objects that are allowed undefined references # # UNREF_OBJ # "unreferenced object=" ldd(1) diagnostics. # # UNUSED_DEPS # Objects that are allowed to have unused dependencies # # UNUSED_OBJ # Objects that are allowed to be unused dependencies # # UNUSED_RPATH # Objects with unused runpaths # use vars qw($EXRE_exec_data $EXRE_exec_stack $EXRE_nocrlealt); use vars qw($EXRE_nodirect $EXRE_nosymsort $EXRE_forbidden_dep $EXRE_forbidden); use vars qw($EXRE_olddep $EXRE_skip $EXRE_stab $EXRE_textrel $EXRE_undef_ref); use vars qw($EXRE_unref_obj $EXRE_unused_deps $EXRE_unused_obj); use vars qw($EXRE_unused_rpath $EXRE_no_comment $EXRE_not_kmod); use strict; use Getopt::Std; use File::Basename; # Reliably compare two OS revisions. Arguments are . # is the string form of a normal numeric comparison operator. sub cmp_os_ver { my @ver1 = split(/\./, $_[0]); my $op = $_[1]; my @ver2 = split(/\./, $_[2]); push @ver2, ("0") x $#ver1 - $#ver2; push @ver1, ("0") x $#ver2 - $#ver1; my $diff = 0; while (@ver1 || @ver2) { if (($diff = shift(@ver1) - shift(@ver2)) != 0) { last; } } return (eval "$diff $op 0" ? 1 : 0); } ## ProcFile(FullPath, RelPath, File, Class, Type, Verdef) # # Determine whether this a ELF dynamic object and if so investigate its runtime # attributes. # sub ProcFile { my($FullPath, $RelPath, $Class, $Type, $Verdef) = @_; my(@Elf, @Ldd, $Dyn, $Sym, $Stack); my($Sun, $Relsz, $Pltsz, $Tex, $Stab, $Strip, $Lddopt, $SymSort); my($Val, $Header, $IsX86, $RWX, $UnDep); my($HasDirectBinding, $HasKMOD); # Ignore symbolic links return if -l $FullPath; # Is this an object or directory hierarchy we don't care about? return if (defined($EXRE_skip) && ($RelPath =~ $EXRE_skip)); # Bail if we can't stat the file. Otherwise, note if it is SUID/SGID. return if !stat($FullPath); my $Secure = (-u _ || -g _) ? 1 : 0; # Reset output message counts for new input file $$ErrTtl = $$InfoTtl = 0; @Ldd = 0; # Determine whether we have access to inspect the file. if (!(-r $FullPath)) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "unable to inspect file: permission denied"); return; } # Determine whether we have a executable (static or dynamic) or a # shared object. @Elf = split(/\n/, `elfdump -epdcy $FullPath 2>&1`); $Dyn = $Stack = $IsX86 = $RWX = $HasKMOD = 0; $Header = 'None'; foreach my $Line (@Elf) { # If we have an invalid file type (which we can tell from the # first line), or we're processing an archive, bail. if ($Header eq 'None') { if (($Line =~ /invalid file/) || ($Line =~ /\Q$FullPath\E(.*):/)) { return; } } if ($Line =~ /^ELF Header/) { $Header = 'Ehdr'; next; } if ($Line =~ /^Program Header/) { $Header = 'Phdr'; $RWX = 0; next; } if ($Line =~ /^Dynamic Section/) { # A dynamic section indicates we're a dynamic object $Header = 'Dyn'; $Dyn = 1; next; } if (($Header eq 'Ehdr') && ($Line =~ /e_machine:/)) { # If it's a X86 object, we need to enforce RW- data. $IsX86 = 1 if $Line =~ /(EM_AMD64|EM_386)/; next; } if (($Header eq 'Phdr') && ($Line =~ /\[ PF_X\s+PF_W\s+PF_R \]/)) { # RWX segment seen. $RWX = 1; next; } if (($Header eq 'Phdr') && ($Line =~ /\[ PT_LOAD \]/ && $RWX && $IsX86)) { # Seen an RWX PT_LOAD segment. if (!defined($EXRE_exec_data) || ($RelPath !~ $EXRE_exec_data)) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "application requires non-executable " . "data\t"); } next; } if (($Header eq 'Phdr') && ($Line =~ /\[ PT_SUNWSTACK \]/)) { # This object defines a non-executable stack. $Stack = 1; next; } if (($Header eq 'Dyn') && ($Line =~ /SUNW_KMOD/)) { $HasKMOD = 1; next; } } # Determine whether this ELF object has a conforming mcs(1) comment # section. If the correct $(POST_PROCESS) macros are used, only a 3 # or 4 line .comment section should exist containing one or two # "@(#)illumos" identifying comments (one comment for a non-debug # build, and two for a debug build). The results of the following # split should be three or four lines, the last empty line being # discarded by the split. if ($opt{m} && (!defined($EXRE_no_comment) || ($RelPath !~ $EXRE_no_comment))) { my(@Mcs, $Con, $Dev); @Mcs = split(/\n/, `mcs -p $FullPath 2>&1`); $Con = $Dev = $Val = 0; foreach my $Line (@Mcs) { $Val++; if (($Val == 3) && ($Line !~ /^@\(#\)illumos/)) { $Con = 1; last; } if (($Val == 4) && ($Line =~ /^@\(#\)illumos/)) { $Dev = 1; next; } if (($Dev == 0) && ($Val == 4)) { $Con = 1; last; } if (($Dev == 1) && ($Val == 5)) { $Con = 1; last; } } if ($opt{m} && ($Con == 1)) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "non-conforming mcs(1) comment\t"); } } # Applications should contain a non-executable stack definition. if (($Type eq 'EXEC') && ($Stack == 0) && (!defined($EXRE_exec_stack) || ($RelPath !~ $EXRE_exec_stack))) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "non-executable stack required\t"); } # Use ldd on dynamic objects unless it's a 64-bit object and we lack # the hardware. if (($Type ne 'REL') && (($Class == 32) || $Ena64)) { my $LDDFullPath = $FullPath; if ($Secure) { # The execution of a secure application over an nfs file # system mounted nosuid will result in warning messages # being sent to /var/adm/messages. As this type of # environment can occur with root builds, move the file # being investigated to a safe place first. In addition # remove its secure permission so that it can be # influenced by any alternative dependency mappings. my $File = $RelPath; $File =~ s!^.*/!!; # basename my($TmpPath) = "$Tmpdir/$File"; system('cp', $LDDFullPath, $TmpPath); chmod 0777, $TmpPath; $LDDFullPath = $TmpPath; } # Use ldd(1) to determine the objects relocatability and use. # By default look for all unreferenced dependencies. However, # some objects have legitimate dependencies that they do not # reference. if ($LddNoU) { $Lddopt = "-ru"; } else { $Lddopt = "-rU"; } @Ldd = split(/\n/, `ldd $Lddopt $Env $LDDFullPath 2>&1`); if ($Secure) { unlink $LDDFullPath; } } $Val = 0; $Sym = 5; $UnDep = 1; foreach my $Line (@Ldd) { if ($Val == 0) { $Val = 1; # Make sure ldd(1) worked. One possible failure is that # this is an old ldd(1) prior to -e addition (4390308). if ($Line =~ /usage:/) { $Line =~ s/$/\t/; onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, $Line); last; } elsif ($Line =~ /execution failed/) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, $Line); last; } # It's possible this binary can't be executed, ie. we've # found a sparc binary while running on an intel system, # or a sparcv9 binary on a sparcv7/8 system. if ($Line =~ /wrong class/) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "has wrong class or data encoding"); next; } # Historically, ldd(1) likes executable objects to have # their execute bit set. if (($Type eq 'EXEC' || $Type eq 'DYN' || $HasKMOD == 1) && (!(-x $FullPath))) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "is not executable"); next; } } # Look for "file" or "versions" that aren't found. Note that # these lines will occur before we find any symbol referencing # errors. if (($Type ne 'REL') && ($Sym == 5) && ($Line =~ /not found\)/)) { if ($Line =~ /file not found\)/) { $Line =~ s/$/\t/; } onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, $Line); next; } # Look for relocations whose symbols can't be found. Note, we # only print out the first 5 relocations for any file as this # output can be excessive. if (($Type ne 'REL') && $Sym && ($Line =~ /symbol not found/)) { # Determine if this file is allowed undefined # references. if (($Sym == 5) && defined($EXRE_undef_ref) && ($RelPath =~ $EXRE_undef_ref)) { $Sym = 0; next; } if ($Sym-- == 1) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "continued ...") if !$opt{o}; next; } # Just print the symbol name. $Line =~ s/$/\t/; onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, $Line); next; } # Look for any unused search paths. if ($Line =~ /unused search path=/) { next if defined($EXRE_unused_rpath) && ($Line =~ $EXRE_unused_rpath); if ($Secure) { $Line =~ s!$Tmpdir/!!; } $Line =~ s/^[ \t]*(.*)/\t$1\t/; onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, $Line); next; } # Look for unreferenced dependencies. Note, if any unreferenced # objects are ignored, then set $UnDep so as to suppress any # associated unused-object messages. if ($Line =~ /unreferenced object=/) { if (defined($EXRE_unref_obj) && ($Line =~ $EXRE_unref_obj)) { $UnDep = 0; next; } if ($Secure) { $Line =~ s!$Tmpdir/!!; } $Line =~ s/^[ \t]*(.*)/$1\t/; onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, $Line); next; } # Look for any unused dependencies. if ($UnDep && ($Line =~ /unused .+=/)) { # Skip if object is allowed to have unused dependencies next if defined($EXRE_unused_deps) && ($RelPath =~ $EXRE_unused_deps); # Skip if dependency is always allowed to be unused next if defined($EXRE_unused_obj) && ($Line =~ $EXRE_unused_obj); $Line =~ s!$Tmpdir/!! if $Secure; $Line =~ s/^[ \t]*(.*)/$1\t/; onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, $Line); next; } } # Reuse the elfdump(1) data to investigate additional dynamic linking # information. $Sun = $Relsz = $Pltsz = $Dyn = $Stab = $SymSort = 0; $Tex = $Strip = 1; $HasDirectBinding = 0; $HasKMOD = 0; $Header = 'None'; ELF: foreach my $Line (@Elf) { # We're only interested in the section headers and the dynamic # section. if ($Line =~ /^Section Header/) { $Header = 'Shdr'; if (($Sun == 0) && ($Line =~ /\.SUNW_reloc/)) { # This object has a combined relocation section. $Sun = 1; } elsif (($Stab == 0) && ($Line =~ /\.stab/)) { # This object contain .stabs sections $Stab = 1; } elsif (($SymSort == 0) && ($Line =~ /\.SUNW_dyn(sym)|(tls)sort/)) { # This object contains a symbol sort section $SymSort = 1; } if (($Strip == 1) && ($Line =~ /\.symtab/)) { # This object contains a complete symbol table. $Strip = 0; } next; } elsif ($Line =~ /^Dynamic Section/) { $Header = 'Dyn'; next; } elsif ($Line =~ /^Syminfo Section/) { $Header = 'Syminfo'; next; } elsif (($Header ne 'Dyn') && ($Header ne 'Syminfo')) { next; } # Look into the Syminfo section. # Does this object have at least one Directly Bound symbol? if (($Header eq 'Syminfo')) { my(@Symword); if ($HasDirectBinding == 1) { next; } @Symword = split(' ', $Line); if (!defined($Symword[1])) { next; } if ($Symword[1] =~ /B/) { $HasDirectBinding = 1; } next; } # Does this object contain text relocations. if ($Tex && ($Type ne 'REL') && ($Line =~ /TEXTREL/)) { # Determine if this file is allowed text relocations. if (defined($EXRE_textrel) && ($RelPath =~ $EXRE_textrel)) { $Tex = 0; next ELF; } onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "TEXTREL .dynamic tag\t\t\t"); $Tex = 0; next; } # Does this file have any relocation sections (there are a few # psr libraries with no relocations at all, thus a .SUNW_reloc # section won't exist either). if (($Relsz == 0) && ($Line =~ / RELA?SZ/)) { $Relsz = hex((split(' ', $Line))[2]); next; } # Does this file have any plt relocations. If the plt size is # equivalent to the total relocation size then we don't have # any relocations suitable for combining into a .SUNW_reloc # section. if (($Pltsz == 0) && ($Line =~ / PLTRELSZ/)) { $Pltsz = hex((split(' ', $Line))[2]); next; } # Does this object have any dependencies. if ($Line =~ /NEEDED/) { my($Need) = (split(' ', $Line))[3]; if (defined($EXRE_olddep) && ($Need =~ $EXRE_olddep)) { # Catch any old (unnecessary) dependencies. onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "NEEDED=$Need\t"); } elsif ((defined($EXRE_forbidden) && ($Need =~ $EXRE_forbidden)) && (!defined($EXRE_forbidden_dep) || ($FullPath !~ $EXRE_forbidden_dep))) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "NEEDED=$Need\t"); } elsif ($opt{i}) { # Under the -i (information) option print out # any useful dynamic entries. onbld_elfmod::OutMsg($InfoFH, $InfoTtl, $RelPath, "NEEDED=$Need"); } next; } # Is this object built with -B direct flag on? if ($Line =~ / DIRECT /) { $HasDirectBinding = 1; } if (($Header eq 'Dyn') && ($Line =~ /SUNW_KMOD/)) { $HasKMOD = 1; } # Does this object specify a runpath. if ($opt{i} && ($Line =~ /RPATH/)) { my($Rpath) = (split(' ', $Line))[3]; onbld_elfmod::OutMsg($InfoFH, $InfoTtl, $RelPath, "RPATH=$Rpath"); next; } } # A shared object, that contains non-plt relocations, should have a # combined relocation section indicating it was built with -z combreloc. if (($Type eq 'DYN') && $Relsz && ($Relsz != $Pltsz) && ($Sun == 0)) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, ".SUNW_reloc section missing\t\t"); } # A probable kernel module should be tagged if (($Type eq 'REL') && ($RelPath =~ qr{(^|/)kernel/}) && ($HasKMOD == 0)) { if (!defined($EXRE_not_kmod) || ($RelPath !~ $EXRE_not_kmod)) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "kernel object should be linked -ztype=kmod"); } } # No objects released to a customer should have any .stabs sections # remaining, they should be stripped. if ($opt{s} && $Stab) { goto DONESTAB if defined($EXRE_stab) && ($RelPath =~ $EXRE_stab); onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "debugging sections should be deleted\t"); } # Identify an object that is not built with either -B direct or # -z direct. goto DONESTAB if (defined($EXRE_nodirect) && ($RelPath =~ $EXRE_nodirect)); if ($Relsz && ($HasDirectBinding == 0)) { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "object has no direct bindings\t"); } DONESTAB: # All objects should have a full symbol table to provide complete # debugging stack traces. onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "symbol table should not be stripped\t") if $Strip; # If there are symbol sort sections in this object, report on # any that have duplicate addresses. ProcSymSort($FullPath, $RelPath) if $SymSort; # If -v was specified, and the object has a version definition # section, generate output showing each public symbol and the # version it belongs to. ProcVerdef($FullPath, $RelPath) if ($Verdef eq 'VERDEF') && $opt{v}; } ## ProcSymSortOutMsg(RelPath, secname, addr, names...) # # Call onbld_elfmod::OutMsg for a duplicate address error in a symbol sort # section # sub ProcSymSortOutMsg { my($RelPath, $secname, $addr, @names) = @_; onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "$secname: duplicate $addr: ". join(', ', @names)); } ## ProcSymSort(FullPath, RelPath) # # Examine the symbol sort sections for the given object and report # on any duplicate addresses found. Ideally, mapfile directives # should be used when building objects that have multiple symbols # with the same address so that only one of them appears in the sort # section. This saves space, reduces user confusion, and ensures that # libproc and debuggers always display public names instead of symbols # that are merely implementation details. # sub ProcSymSort { my($FullPath, $RelPath) = @_; # If this object is exempt from checking, return quietly return if defined($EXRE_nosymsort) && ($FullPath =~ $EXRE_nosymsort); open(SORT, "elfdump -S $FullPath|") || die "$Prog: Unable to execute elfdump (symbol sort sections)\n"; my $line; my $last_addr; my @dups = (); my $secname; while ($line = ) { chomp $line; next if ($line eq ''); # If this is a header line, pick up the section name if ($line =~ /^Symbol Sort Section:\s+([^\s]+)\s+/) { $secname = $1; # Every new section is followed by a column header line $line = ; # Toss header line # Flush anything left from previous section ProcSymSortOutMsg($RelPath, $secname, $last_addr, @dups) if (scalar(@dups) > 1); # Reset variables for new sort section $last_addr = ''; @dups = (); next; } # Process symbol line my @fields = split /\s+/, $line; my $new_addr = $fields[2]; my $new_type = $fields[8]; my $new_name = $fields[9]; if ($new_type eq 'UNDEF') { onbld_elfmod::OutMsg($ErrFH, $ErrTtl, $RelPath, "$secname: unexpected UNDEF symbol " . "(link-editor error): $new_name"); next; } if ($new_addr eq $last_addr) { push @dups, $new_name; } else { ProcSymSortOutMsg($RelPath, $secname, $last_addr, @dups) if (scalar(@dups) > 1); @dups = ( $new_name ); $last_addr = $new_addr; } } ProcSymSortOutMsg($RelPath, $secname, $last_addr, @dups) if (scalar(@dups) > 1); close SORT; } ## ProcVerdef(FullPath, RelPath) # # Examine the version definition section for the given object and report # each public symbol along with the version it belongs to. # sub ProcVerdef { my($FullPath, $RelPath) = @_; my $line; my $cur_ver = ''; my $tab = $opt{o} ? '' : "\t"; # pvs -dov provides information about the versioning hierarchy # in the file. Lines are of the format: # path - version[XXX]; # where [XXX] indicates optional information, such as flags # or inherited versions. # # Private versions are allowed to change freely, so ignore them. open(PVS, "pvs -dov $FullPath|") || die "$Prog: Unable to execute pvs (version definition section)\n"; while ($line = ) { chomp $line; if ($line =~ /^[^\s]+\s+-\s+([^;]+)/) { my $ver = $1; next if $ver =~ /private/i; onbld_elfmod::OutMsg($InfoFH, $InfoTtl, $RelPath, "${tab}VERDEF=$ver"); } } close PVS; # pvs -dos lists the symbols assigned to each version definition. # Lines are of the format: # path - version: symbol; # path - version: symbol (size); # where the (size) is added to data items, but not for functions. # We strip off the size, if present. open(PVS, "pvs -dos $FullPath|") || die "$Prog: Unable to execute pvs (version definition section)\n"; while ($line = ) { chomp $line; if ($line =~ /^[^\s]+\s+-\s+([^:]+):\s*([^\s;]+)/) { my $ver = $1; my $sym = $2; next if $ver =~ /private/i; if ($opt{o}) { onbld_elfmod::OutMsg($InfoFH, $InfoTtl, $RelPath, "VERSION=$ver, SYMBOL=$sym"); } else { if ($cur_ver ne $ver) { onbld_elfmod::OutMsg($InfoFH, $InfoTtl, $RelPath, "VERSION=$ver"); $cur_ver = $ver; } onbld_elfmod::OutMsg($InfoFH, $InfoTtl, $RelPath, "SYMBOL=$sym"); } } } close PVS; } ## OpenFindElf(file, FileHandleRef, LineNumRef) # # Open file in 'find_elf -r' format, and return the value of # the opening PREFIX line. # # entry: # file - file, or find_elf child process, to open # FileHandleRef - Reference to file handle to open # LineNumRef - Reference to integer to increment as lines are input # # exit: # This routine issues a fatal error and does not return on error. # Otherwise, the value of PREFIX is returned. # sub OpenFindElf { my ($file, $fh, $LineNum) = @_; my $line; my $prefix; open($fh, $file) || die "$Prog: Unable to open: $file"; $$LineNum = 0; # This script requires relative paths as created by 'find_elf -r'. # When this is done, the first non-comment line will always # be PREFIX. Obtain that line, or issue a fatal error. while ($line = onbld_elfmod::GetLine($fh, $LineNum)) { if ($line =~ /^PREFIX\s+(.*)$/i) { $prefix = $1; last; } die "$Prog: No PREFIX line seen on line $$LineNum: $file"; } $prefix; } ## ProcFindElf(file) # # Open the specified file, which must be produced by "find_elf -r", # and process the files it describes. # sub ProcFindElf { my $file = $_[0]; my $line; my $LineNum; my $prefix = OpenFindElf($file, \*FIND_ELF, \$LineNum); while ($line = onbld_elfmod::GetLine(\*FIND_ELF, \$LineNum)) { next if !($line =~ /^OBJECT\s/i); my ($item, $class, $type, $verdef, $obj) = split(/\s+/, $line, 5); ProcFile("$prefix/$obj", $obj, $class, $type, $verdef); } close FIND_ELF; } ## AltObjectConfig(file) # # Recurse through a directory hierarchy looking for appropriate dependencies # to map from their standard system locations to the proto area via a crle # config file. # # entry: # file - File of ELF objects, in 'find_elf -r' format, to examine. # # exit: # Scripts are generated for the 32 and 64-bit cases to run crle # and create runtime configuration files that will establish # alternative dependency mappings for the objects identified. # # $Env - Set to environment variable definitions that will cause # the config files generated by this routine to be used # by ldd. # $Conf32, $Conf64 - Undefined, or set to the config files generated # by this routine. If defined, the caller is responsible for # unlinking the files before exiting. # sub AltObjectConfig { my $file = $_[0]; my ($Crle32, $Crle64); my $line; my $LineNum; my $obj_path; my $obj_active = 0; my $obj_class; my $prefix = OpenFindElf($file, \*FIND_ELF); LINE: while ($line = onbld_elfmod::GetLine(\*FIND_ELF, \$LineNum)) { ITEM: { if ($line =~ /^OBJECT\s/i) { my ($item, $class, $type, $verdef, $obj) = split(/\s+/, $line, 5); if ($type eq 'DYN') { $obj_active = 1; $obj_path = $obj; $obj_class = $class; } else { # Only want sharable objects $obj_active = 0; } last ITEM; } # We need to follow links to sharable objects so # that any dependencies are expressed in all their # available forms. We depend on ALIAS lines directly # following the object they alias, so if we have # a current object, this alias belongs to it. if ($obj_active && ($line =~ /^ALIAS\s/i)) { my ($item, $real_obj, $obj) = split(/\s+/, $line, 3); $obj_path = $obj; last ITEM; } # Skip unrecognized item next LINE; } next if !$obj_active; my $full = "$prefix/$obj_path"; next if defined($EXRE_nocrlealt) && ($obj_path =~ $EXRE_nocrlealt); my $Dir = $full; $Dir =~ s/^(.*)\/.*$/$1/; # Create a crle(1) script for the dependency we've found. # We build separate scripts for the 32 and 64-bit cases. # We create and initialize each script when we encounter # the first object that needs it. if ($obj_class == 32) { if (!$Crle32) { $Crle32 = "$Tmpdir/$Prog.crle32.$$"; open(CRLE32, "> $Crle32") || die "$Prog: open failed: $Crle32: $!"; print CRLE32 "#!/bin/sh\ncrle \\\n"; } print CRLE32 "\t-o $Dir -a /$obj_path \\\n"; } elsif ($Ena64) { if (!$Crle64) { $Crle64 = "$Tmpdir/$Prog.crle64.$$"; open(CRLE64, "> $Crle64") || die "$Prog: open failed: $Crle64: $!"; print CRLE64 "#!/bin/sh\ncrle -64\\\n"; } print CRLE64 "\t-o $Dir -a /$obj_path \\\n"; } } close FIND_ELF; # Now that the config scripts are complete, use them to generate # runtime linker config files. if ($Crle64) { $Conf64 = "$Tmpdir/$Prog.conf64.$$"; print CRLE64 "\t-c $Conf64\n"; chmod 0755, $Crle64; close CRLE64; undef $Conf64 if system($Crle64); # Done with the script unlink $Crle64; } if ($Crle32) { $Conf32 = "$Tmpdir/$Prog.conf32.$$"; print CRLE32 "\t-c $Conf32\n"; chmod 0755, $Crle32; close CRLE32; undef $Conf32 if system($Crle32); # Done with the script unlink $Crle32; } # Set $Env so that we will use the config files generated above # when we run ldd. if ($Crle64 && $Conf64 && $Crle32 && $Conf32) { $Env = "-e LD_FLAGS=config_64=$Conf64,config_32=$Conf32"; } elsif ($Crle64 && $Conf64) { $Env = "-e LD_FLAGS=config_64=$Conf64"; } elsif ($Crle32 && $Conf32) { $Env = "-e LD_FLAGS=config_32=$Conf32"; } } # ----------------------------------------------------------------------------- # This script relies on ldd returning output reflecting only the binary # contents. But if LD_PRELOAD* environment variables are present, libraries # named by them will also appear in the output, disrupting our analysis. # So, before we get too far, scrub the environment. delete($ENV{LD_PRELOAD}); delete($ENV{LD_PRELOAD_32}); delete($ENV{LD_PRELOAD_64}); # Establish a program name for any error diagnostics. chomp($Prog = `basename $0`); # The onbld_elfmod package is maintained in the same directory as this # script, and is installed in ../lib/perl. Use the local one if present, # and the installed one otherwise. my $moddir = dirname($0); $moddir = "$moddir/../lib/perl" if ! -f "$moddir/onbld_elfmod.pm"; require "$moddir/onbld_elfmod.pm"; # Determine what machinery is available. my $Mach = `uname -p`; my$Isalist = `isalist`; if ($Mach =~ /sparc/) { if ($Isalist =~ /sparcv9/) { $Ena64 = "ok"; } } elsif ($Mach =~ /i386/) { if ($Isalist =~ /amd64/) { $Ena64 = "ok"; } } # $Env is used with all calls to ldd. It is set by AltObjectConfig to # cause an alternate object mapping runtime config file to be used. $Env = ''; # Check that we have arguments. if ((getopts('D:d:E:e:f:I:imosvw:', \%opt) == 0) || (!$opt{f} && ($#ARGV == -1))) { print "usage: $Prog [-imosv] [-D depfile | -d depdir] [-E errfile]\n"; print "\t\t[-e exfile] [-f listfile] [-I infofile] [-w outdir]\n"; print "\t\t[file | dir]...\n"; print "\n"; print "\t[-D depfile]\testablish dependencies from 'find_elf -r' file list\n"; print "\t[-d depdir]\testablish dependencies from under directory\n"; print "\t[-E errfile]\tdirect error output to file\n"; print "\t[-e exfile]\texceptions file\n"; print "\t[-f listfile]\tuse file list produced by find_elf -r\n"; print "\t[-I infofile]\tdirect informational output (-i, -v) to file\n"; print "\t[-i]\t\tproduce dynamic table entry information\n"; print "\t[-m]\t\tprocess mcs(1) comments\n"; print "\t[-o]\t\tproduce one-liner output (prefixed with pathname)\n"; print "\t[-s]\t\tprocess .stab and .symtab entries\n"; print "\t[-v]\t\tprocess version definition entries\n"; print "\t[-w outdir]\tinterpret all files relative to given directory\n"; exit 1; } die "$Prog: -D and -d options are mutually exclusive\n" if ($opt{D} && $opt{d}); $Tmpdir = "/tmp" if (!($Tmpdir = $ENV{TMPDIR}) || (! -d $Tmpdir)); # If -w, change working directory to given location !$opt{w} || chdir($opt{w}) || die "$Prog: can't cd to $opt{w}"; # Locate and process the exceptions file onbld_elfmod::LoadExceptionsToEXRE('check_rtime'); # Is there a proto area available, either via the -d option, or because # we are part of an activated workspace? my $Proto; if ($opt{d}) { # User specified dependency directory - make sure it exists. -d $opt{d} || die "$Prog: $opt{d} is not a directory\n"; $Proto = $opt{d}; } elsif ($ENV{CODEMGR_WS}) { my $Root; # Without a user specified dependency directory see if we're # part of a codemanager workspace and if a proto area exists. $Proto = $Root if ($Root = $ENV{ROOT}) && (-d $Root); } # If we are basing this analysis off the sharable objects found in # a proto area, then gather dependencies and construct an alternative # dependency mapping via a crle(1) configuration file. # # To support alternative dependency mapping we'll need ldd(1)'s # -e option. This is relatively new (s81_30), so make sure # ldd(1) is capable before gathering any dependency information. if ($opt{D} || $Proto) { if (system('ldd -e /usr/lib/lddstub 2> /dev/null')) { print "ldd: does not support -e, unable to "; print "create alternative dependency mappingings.\n"; print "ldd: option added under 4390308 (s81_30).\n\n"; } else { # If -D was specified, it supplies a list of files in # 'find_elf -r' format, and can use it directly. Otherwise, # we will run find_elf as a child process to find the # sharable objects found under $Proto. AltObjectConfig($opt{D} ? $opt{D} : "find_elf -frs $Proto|"); } } # To support unreferenced dependency detection we'll need ldd(1)'s -U # option. This is relatively new (4638070), and if not available we # can still fall back to -u. Even with this option, don't use -U with # releases prior to 5.10 as the cleanup for -U use only got integrated # into 5.10 under 4642023. Note, that nightly doesn't typically set a # RELEASE from the standard files. Users who wish to disable use # of ldd(1)'s -U should set (or uncomment) RELEASE in their file # if using nightly, or otherwise establish it in their environment. if (system('ldd -U /usr/lib/lddstub 2> /dev/null')) { $LddNoU = 1; } else { my($Release); if (($Release = $ENV{RELEASE}) && (cmp_os_ver($Release, "<", "5.10"))) { $LddNoU = 1; } else { $LddNoU = 0; } } # Set up variables used to handle output files: # # Error messages go to stdout unless -E is specified. $ErrFH is a # file handle reference that points at the file handle where error messages # are sent, and $ErrTtl is a reference that points at an integer used # to count how many lines have been sent there. # # Informational messages go to stdout unless -I is specified. $InfoFH is a # file handle reference that points at the file handle where info messages # are sent, and $InfoTtl is a reference that points at an integer used # to count how many lines have been sent there. # if ($opt{E}) { open(ERROR, ">$opt{E}") || die "$Prog: open failed: $opt{E}"; $ErrFH = \*ERROR; } else { $ErrFH = \*STDOUT; } if ($opt{I}) { open(INFO, ">$opt{I}") || die "$Prog: open failed: $opt{I}"; $InfoFH = \*INFO; } else { $InfoFH = \*STDOUT; } my ($err_dev, $err_ino) = stat($ErrFH); my ($info_dev, $info_ino) = stat($InfoFH); $ErrTtl = \$OutCnt1; $InfoTtl = (($err_dev == $info_dev) && ($err_ino == $info_ino)) ? \$OutCnt1 : \$OutCnt2; # If we were given a list of objects in 'find_elf -r' format, then # process it. ProcFindElf($opt{f}) if $opt{f}; # Process each argument foreach my $Arg (@ARGV) { # Run find_elf to find the files given by $Arg and process them ProcFindElf("find_elf -fr $Arg|"); } # Cleanup output files unlink $Conf64 if $Conf64; unlink $Conf32 if $Conf32; close ERROR if $opt{E}; close INFO if $opt{I}; exit 0;