# Copyright 1998, 2000, 2001, 2002, 2003, 2004 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 2 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, write to the Free Software # Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. # # Please email any bugs, comments, and/or additions to this file to: # bug-gdb@prep.ai.mit.edu # # This file was written by Kendra. if $tracelevel then { strace $tracelevel } # # Test debugging assembly level programs. # This file uses asmsrc[12].s for input. # set prms_id 0 set bug_id 0 set asm-arch "" set asm-note "empty" set asm-flags "" set link-flags "--entry _start" switch -glob -- [istarget] { "alpha*-*-*" { set asm-arch alpha # ??? Won't work with ecoff systems like Tru64, but then we also # don't have any other -g flag that creates mdebug output. set asm-flags "-gdwarf2 -no-mdebug -I${srcdir}/${subdir} -I${objdir}/${subdir}" } "*arm-*-*" { set asm-arch arm } "xscale-*-*" { set asm-arch arm } "d10v-*-*" { set asm-arch d10v } "frv-*-*" { set asm-arch frv } "s390-*-*" { set asm-arch s390 } "s390x-*-*" { set asm-arch s390x } "x86_64-*-*" { set asm-arch x86_64 set asm-flags "-gdwarf2 -I${srcdir}/${subdir} -I${objdir}/${subdir}" } "i\[3456\]86-*-*" { set asm-arch i386 } "m32r*-*" { set asm-arch m32r append link-flags " -Wl,--whole-archive -lgloss -Wl,--no-whole-archive" } "m6811-*-*" { set asm-arch m68hc11 set asm-flags "-mshort-double -m68hc11 -gdwarf2 --no-warn -I${srcdir}/${subdir} -I${objdir}/${subdir}" } "m6812-*-*" { set asm-arch m68hc11 set asm-flags "-mshort-double -m68hc12 -gdwarf2 --no-warn -I${srcdir}/${subdir} -I${objdir}/${subdir}" } "mips*-*" { set asm-arch mips } "powerpc*-*" { set asm-arch powerpc } "sh*-*-*" { set asm-arch sh set asm-flags "-gdwarf2 -I${srcdir}/${subdir} -I${objdir}/${subdir}" } "sparc-*-*" { set asm-arch sparc } "sparc64-*-*" { set asm-arch sparc64 set asm-flags "-xarch=v9 -gstabs -I${srcdir}/${subdir} -I${objdir}/${subdir}" } "xstormy16-*-*" { set asm-arch xstormy16 set asm-flags "-gdwarf2 -I${srcdir}/${subdir} -I${objdir}/${subdir}" } "v850-*-*" { set asm-arch v850 set gdb_wrapper_initialized 1 } "m68k-*-*" { set asm-arch m68k } "ia64-*-*" { set asm-arch ia64 set asm-flags "-gdwarf2 -I${srcdir}/${subdir} -I${objdir}/${subdir}" } } if { "${asm-arch}" == "" } { gdb_suppress_entire_file "Assembly source test -- not implemented for this target." } # On FreeBSD and NetBSD, the final link will fail because of # unresolved symbols. It turns out that libc.so references symbols # that are normally provided by crt1.o, which isn't linked in since we # specify -nostartfiles. Using -nostdlib doesn't help since # target_compile automatically adds -lm. Linking statically avoids # this mess. # # On Solaris, linking dynamically results in a binary that dumps core. # if {[istarget "*-*-freebsd*"] || [istarget "*-*-netbsd*"] || [istarget "*-*-solaris2*"]} then { append link-flags " -static" } # On NetBSD/ELF we need a special NetBSD-identifying note section. if { [istarget "*-*-netbsdelf*"] || [istarget "x86_64-*-netbsd*"] } then { set asm-note "netbsd" } # Watch out, we are invoking the assembler, but the testsuite sets multilib # switches according to compiler syntax. If we pass these options straight # to the assembler, they won't always make sense. If we don't pass them to # the assembler, the final link will complain that the object files were # built with different defaults. So no matter what we do, we lose. We may as # well get out of this test sooner rather than later. set dest [target_info name] if [board_info $dest exists multilib_flags] { set multilib_flags [board_info $dest multilib_flags] if { "${multilib_flags}" != "" } { gdb_suppress_entire_file "Assembly source test -- multilibs not supported by this test." return; } } set testfile "asm-source" set binfile ${objdir}/${subdir}/${testfile} set srcfile1 asmsrc1.s set srcfile2 asmsrc2.s remote_exec build "rm -f ${subdir}/arch.inc" remote_download host ${srcdir}/${subdir}/${asm-arch}.inc ${subdir}/arch.inc remote_exec build "rm -f ${subdir}/note.inc" remote_download host ${srcdir}/${subdir}/${asm-note}.inc ${subdir}/note.inc if { "${asm-flags}" == "" } { #set asm-flags "-Wa,-gstabs,-I${srcdir}/${subdir},-I${objdir}/${subdir}" set asm-flags "-gstabs -I${srcdir}/${subdir} -I${objdir}/${subdir}" } if {[target_assemble ${srcdir}/${subdir}/${srcfile1} asmsrc1.o "${asm-flags}"] != ""} then { gdb_suppress_entire_file "Testcase compile failed, so all tests in this file will automatically fail." } if {[target_assemble ${srcdir}/${subdir}/${srcfile2} asmsrc2.o "${asm-flags}"] != ""} then { gdb_suppress_entire_file "Testcase compile failed, so all tests in this file will automatically fail." } set opts "debug ldflags=-nostartfiles" foreach i ${link-flags} { append opts " ldflags=$i" } if { [gdb_compile "asmsrc1.o asmsrc2.o" "${binfile}" executable $opts] != "" } { gdb_suppress_entire_file "Testcase compile failed, so all tests in this file will automatically fail." } remote_exec build "mv asmsrc1.o asmsrc2.o ${objdir}/${subdir}" gdb_start gdb_reinitialize_dir $srcdir/$subdir gdb_load ${binfile} # # Run to `main' where we begin our tests. # if ![runto_main] then { gdb_suppress_tests } # Execute the `f' command and see if the result includes source info. gdb_test "f" "asmsrc1\[.\]s:29.*several_nops" "f at main" # See if we properly `next' over a macro with several insns. gdb_test "n" "33\[ \]*.*foo2" "next over macro" # See if we can properly `step' into a subroutine call. gdb_test "s" "8\[ \]*.*" "step into foo2" # Test 'info target', and incidentally capture the entry point address. set entry_point 0 send_gdb "info target\n" gdb_expect { -re "Symbols from .*asm-source.*Entry point: 0x(\[01232456789abcdefABCDEF\]+).*$gdb_prompt $" { set entry_point $expect_out(1,string) pass "info target" } -re ".*$gdb_prompt $" { fail "info target" } timeout { fail "info target (timeout)" } } # Capture the start symbol (may be '_start' or 'start') set entry_symbol "" send_gdb "info symbol 0x$entry_point\n" gdb_expect { -re "info symbol 0x$entry_point\[\r\n\]+(\[^\r\n\]*) in section .*$gdb_prompt $" { # We match the echoed `info symbol' command here, to help us # reliably identify the beginning of the start symbol in the # command's output. You might think we could just use '^' to # start matching at the beginning of the line, but # unfortunately, in Expect, '^' matches the beginning of the # input that hasn't been matched by any expect clause yet. If # every expect clause consumes a complete line, along with its # terminating CR/LF, this is equivalent to the beginning of a # line. But expect clauses that end with `.*' will consume as # much as happened to arrive from the TTY --- exactly where # they leave you depends on inter-process timing. :( set entry_symbol $expect_out(1,string) pass "info symbol" } -re ".*$gdb_prompt $" { fail "info symbol" } timeout { fail "info symbol (timeout)" } } # Now try a 'list' from the other source file. gdb_test "list $entry_symbol" ".*gdbasm_startup.*" "list" # Now try a source file search gdb_test "search A routine for foo2 to call" \ "40\[ \t\]+comment \"A routine for foo2 to call.\"" "search" # See if `f' prints the right source file. gdb_test "f" ".*asmsrc2\[.\]s:8.*" "f in foo2" # `next' one insn (or macro) to set up our stackframe (for the following bt). gdb_test "n" "12\[ \]*.*foo3" "n in foo2" # See if a simple `bt' prints the right source files and # doesn't fall off the stack. gdb_test "bt 10" \ "\#0.*foo2.*asmsrc2\[.\]s:12.*\#1.*main.*asmsrc1\[.\]s:33" \ "bt ALL in foo2" # See if a capped `bt' prints the right source files. gdb_test "bt 2" "\#0.*foo2.*asmsrc2\[.\]s:12.*\#1.*main.*asmsrc1\[.\]s:33.*" "bt 2 in foo2" # Step into another subroutine which lives back in the first source file. gdb_test "s" "" "s 2" # Next over insns to set up the stack frame. gdb_test "n" "" "n 2" # Now see if a capped `bt' is correct. gdb_test "bt 3" "\#0.*foo3.*asmsrc1\[.\]s:45.*\#1.*foo2.*asmsrc2\[.\]s:12.*\#2.*main.*asmsrc1\[.\]s:33.*" "bt 3 in foo3" # Try 'info source' from asmsrc1.s gdb_test "info source" \ "Current source file is .*asmsrc1.s.*Source language is asm.*" \ "info source asmsrc1.s" # Try 'finishing' from foo3 gdb_test "finish" "Run till exit from.*\[\r\n\]13\[ \t\]+gdbasm_call foo3" \ "finish from foo3" # Try 'info source' from asmsrc2.s gdb_test "info source" \ "Current source file is .*asmsrc2.s.*Source language is asm.*" \ "info source asmsrc2.s" # Try 'info sources'. This can produce a lot of output on systems # with dynamic linking, where the system's shared libc was compiled # with debugging info; for example, on Linux, this produces 47kb of # output. So we consume it as we go. send_gdb "info sources\n" set seen_asmsrc_1 0 set seen_asmsrc_2 0 gdb_expect { -re "^\[^,\]*asmsrc1.s(, |\[\r\n\]+)" { set seen_asmsrc_1 1 exp_continue } -re "^\[^,\]*asmsrc2.s(, |\[\r\n\]+)" { set seen_asmsrc_2 1 exp_continue } -re ", " { exp_continue } -re "$gdb_prompt $" { if {$seen_asmsrc_1 && $seen_asmsrc_2} { pass "info sources" } else { fail "info sources" } } timeout { fail "info sources (timeout)" } } # Try 'info line' gdb_test "info line" \ "Line 13 of.*asmsrc2.s.*starts at.* and ends at.*." \ "info line" # Try 'nexting' over next call to foo3 gdb_test "next" "17\[ \t\]+gdbasm_leave" "next over foo3" # Try 'return' from foo2 gdb_test "return" "\#0 main .*37\[ \t\]+gdbasm_exit0" "return from foo2" \ "Make (foo2|selected stack frame) return now\?.*" "y" # Disassemble something, check the output proc test_dis { command var } { global gdb_prompt send_gdb "${command}\n" gdb_expect { -re "${var}.*:.*(Cannot access|Bad address)" { # The "disassembler" was only accessing the local # executable and that would cause attempts to disassemble # variables to fail (memory not valid). fail "${command} (memory read error)" } -re "${var}.*:.*${gdb_prompt}" { pass "${command}" } timeout { fail "${command} (timeout)" } } } # See if we can look at a global variable, three ways gdb_test "print globalvar" ".* = 11" "look at global variable" test_dis "x/i &globalvar" "globalvar" test_dis "disassem &globalvar &globalvar+1" "globalvar" # See if we can look at a static variable, three ways gdb_test "print staticvar" ".* = 5" "look at static variable" test_dis "x/i &staticvar" "staticvar" test_dis "disassem &staticvar &staticvar+1" "staticvar" # See if we can look at a static function gdb_test "disassem foostatic" ".*:.*End of assembler dump." \ "look at static function" remote_exec build "rm -f ${subdir}/arch.inc" remote_exec build "rm -f ${subdir}/note.inc"