# Copyright (C) 2010-2013 Free Software Foundation, Inc. # This program is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 3 of the License, or # (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see . # Return nul-terminated string read from section SECTION of EXEC. Return "" # if no such section or nul-terminated string was found. Function is useful # for sections ".interp" or ".gnu_debuglink". proc section_get {exec section} { global subdir set tmp [standard_output_file section_get.tmp] set objcopy_program [gdb_find_objcopy] set command "exec $objcopy_program -O binary --set-section-flags $section=A --change-section-address $section=0 -j $section $exec $tmp" verbose -log "command is $command" set result [catch $command output] verbose -log "result is $result" verbose -log "output is $output" if {$result == 1} { return "" } set fi [open $tmp] fconfigure $fi -translation binary set data [read $fi] close $fi file delete $tmp # .interp has size $len + 1 but .gnu_debuglink contains garbage after \000. set len [string first \000 $data] if {$len < 0} { verbose -log "section $section not found" return "" } set retval [string range $data 0 [expr $len - 1]] verbose -log "section $section is <$retval>" return $retval } # Resolve symlinks. proc symlink_resolve {file} { set loop 0 while {[file type $file] == "link"} { set target [file readlink $file] if {[file pathtype $target] == "relative"} { set src2 [file dirname $file]/$target } else { set src2 $target } verbose -log "Resolved symlink $file targetting $target as $src2" set file $src2 set loop [expr $loop + 1] if {$loop > 30} { fail "Looping symlink resolution for $file" return "" } } return $file } # Copy SRC to DEST, resolving any symlinks in SRC. Return nonzero iff # the copy was succesful. # # This function is guaranteed to never raise any exception, even when the copy # fails. proc file_copy {src dest} { set src [symlink_resolve $src] # Test name would contain unstable directory name for symlink-unresolved # $src. set test "copy [file tail $src] to [file tail $dest]" set command "file copy -force -- $src $dest" verbose -log "command is $command" if [catch $command] { fail $test return 0 } else { pass $test return 1 } } # Wrap function build_executable so that the resulting executable is fully # self-sufficient (without dependencies on system libraries). Parameter # INTERP may be used to specify a loader (ld.so) to be used that is # different from the default system one. INTERP can be set to "no" if no ld.so # copy should be made. Libraries on which the executable depends are copied # into directory DIR. Default DIR value to # `${objdir}/${subdir}/${EXECUTABLE}.d'. # # In case of success, return a string containing the arguments to be used # in order to perform a prelink of the executable obtained. Return the # empty string in case of failure. # # This can be useful when trying to prelink an executable which might # depend on system libraries. To properly prelink an executable, all # of its dynamically linked libraries must be prelinked as well. If # the executable depends on some system libraries, we may not have # sufficient write priviledges on these files to perform the prelink. # This is why we make a copy of these shared libraries, and link the # executable against these copies instead. # # Function recognizes only libraries listed by `ldd' after # its ` => ' separator. That means $INTERP and any libraries not being linked # with -Wl,-soname,NAME.so are not copied. proc build_executable_own_libs {testname executable sources options {interp ""} {dir ""}} { global subdir if {[build_executable $testname $executable $sources $options] == -1} { return "" } set binfile [standard_output_file ${executable}] set ldd [gdb_find_ldd] set command "$ldd $binfile" set test "ldd $executable" set result [catch "exec $command" output] verbose -log "result of $command is $result" verbose -log "output of $command is $output" if {$result != 0 || $output == ""} { fail $test } else { pass $test } # gdb testsuite will put there also needless -lm. set test "$test output contains libs" set libs [regexp -all -inline -line {^.* => (/[^ ]+).*$} $output] if {[llength $libs] == 0} { fail $test } else { pass $test } if {$dir == ""} { set dir ${binfile}.d } file delete -force -- $dir file mkdir $dir if {$interp == ""} { set interp_system [section_get $binfile .interp] if {$interp_system == ""} { fail "$test could not find .interp" } else { set interp ${dir}/[file tail $interp_system] file_copy $interp_system $interp } } if {$interp == "no"} { set interp "" } set dests {} foreach {trash abspath} $libs { set dest "$dir/[file tail $abspath]" file_copy $abspath $dest lappend dests $dest } # Do not lappend it so that "-rpath $dir" overrides any possible "-rpath"s # specified by the caller to be able to link it for ldd" above. set options [linsert $options 0 "ldflags=-Wl,-rpath,$dir"] if {$interp != ""} { set options [linsert $options 0 "ldflags=-Wl,--dynamic-linker,$interp"] } if {[build_executable $testname $executable $sources $options] == -1} { return "" } set prelink_args "--ld-library-path=$dir $binfile [concat $dests]" if {$interp != ""} { set prelink_args "--dynamic-linker=$interp $prelink_args $interp" } return $prelink_args } # Unprelink ARG. Reported test name can be specified by NAME. Return non-zero # on success, zero on failure. proc prelink_no {arg {name {}}} { if {$name == ""} { set name [file tail $arg] } set test "unprelink $name" set command "exec /usr/sbin/prelink -uN $arg" verbose -log "command is $command" set result [catch $command output] verbose -log "result is $result" verbose -log "output is $output" if {$result == 1 && [regexp {^(couldn't execute "/usr/sbin/prelink[^\r\n]*": no such file or directory\n?)*$} $output]} { # Without prelink, at least verify that all the binaries do not # contain the ".gnu.prelink_undo" section (which would mean that they # have already been prelinked). set test "$test (missing /usr/sbin/prelink)" foreach bin [split $arg] { if [string match "-*" $bin] { # Skip prelink options. continue } set readelf_program [gdb_find_readelf] set command "exec $readelf_program -WS $bin" verbose -log "command is $command" set result [catch $command output] verbose -log "result is $result" verbose -log "output is $output" if {$result != 0 || [string match {* .gnu.prelink_undo *} $output]} { fail "$test ($bin is already prelinked)" return 0 } } pass $test return 1 } if {$result == 0 && $output == ""} { verbose -log "$name has been now unprelinked" set command "exec /usr/sbin/prelink -uN $arg" verbose -log "command is $command" set result [catch $command output] verbose -log "result is $result" verbose -log "output is $output" } # Last line does miss the trailing \n. There can be multiple such messages # as ARG may list multiple files. if {$result == 1 && [regexp {^([^\r\n]*prelink[^\r\n]*: [^ ]* does not have .gnu.prelink_undo section\n?)*$} $output]} { pass $test return 1 } else { fail $test return 0 } } # Prelink ARG. Reported test name can be specified by NAME. Return non-zero # on success, zero on failure. proc prelink_yes {arg {name ""}} { if {$name == ""} { set name [file tail $arg] } # Try to unprelink it first so that, if it has been already prelinked # before, we get a different address now, making the new result unaffected # by any previous prelinking. if ![prelink_no $arg "$name pre-unprelink"] { return 0 } set test "prelink $name" # `--no-exec-shield' is for i386, where prelink in the exec-shield mode is # forced to push all the libraries tight together, in order to fit into # the first two memory areas (either the ASCII Shield area or at least # below the executable). If the prelink was performed in exec-shield # mode, prelink could have no choice on how to randomize the single new # unprelinked library address without wasting space in the first one/two # memory areas. In such case prelink could place $ARG repeatedly at the # same place and we could have false prelink results on # gdb.base/prelink.exp and others. To prevent this from happening, we use # the --no-exec-shield switch. This may have some consequences in terms # of security, but we do not care in our case. set command "exec /usr/sbin/prelink -qNR --no-exec-shield $arg" verbose -log "command is $command" set result [catch $command output] verbose -log "result is $result" verbose -log "output is $output" if {$result == 1 && [regexp {^(couldn't execute "/usr/sbin/prelink[^\r\n]*": no such file or directory\n?)*$} $output]} { set test "$test (missing /usr/sbin/prelink)" # We could not find prelink. We could check whether $args is already # prelinked but we don't, because: # - It is unlikely that someone uninstalls prelink after having # prelinked the system ld.so; # - We still cannot change its prelinked address. # Therefore, we just skip the test. xfail $test return 0 } if {$result == 1 && [regexp {DWARF [^\r\n]* unhandled} $output]} { # Prelink didn't understand the version of dwarf present. unsupported "$test (dwarf version unhandled)" return 0 } if {$result == 0 && $output == ""} { pass $test return 1 } elseif {$result == 1 \ && [string match -nocase "*: Not enough room to add .dynamic entry" $output]} { # Linker should have reserved some entries for prelink. xfail $test return 0 } else { fail $test return 0 } }