# Copyright (C) 2014-2022 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 . # This file is part of the gdb testsuite. # Test stepping over permanent breakpoints. standard_testfile set options { debug } if { ![target_info exists gdb,nosignals] } { lappend options "additional_flags=-DSIGNALS" } if {[build_executable "failed to prepare" $testfile $srcfile $options]} { return -1 } set line_bp [gdb_get_line_number "write permanent bp"] # The test proper. ALWAYS_INSERTED indicates whether testing in # "breakpoint always-inserted" mode. If SW_WATCHPOINT is true, set a # software watchpoint, which forces constantly single-stepping, and # exercises stepping the permanent breakpoint while delivering a # signal at the same time. proc test {always_inserted sw_watchpoint} { global line_bp global hex decimal global gdb_prompt global srcfile binfile clean_restart $binfile if ![runto_main] then { return -1 } gdb_test "set breakpoint always-inserted $always_inserted" if {$sw_watchpoint} { # Watching a convenience variable forces a software # watchpoint. gdb_test "watch \$dummy_convenience" "Watchpoint .*" } set address_bp "" set address_after_bp "" with_test_prefix "setup" { # Set a breakpoint where we'll manually plant a permanent # breakpoint. set test "set probe breakpoint" gdb_test_multiple "break $line_bp" $test { -re "Breakpoint .* at ($hex).*$gdb_prompt $" { set address_bp $expect_out(1,string) pass $test } } if {$address_bp == ""} { return } # Get the size of the instruction where the breakpoint will # manually inserted. set test "get size of instruction" gdb_test_multiple "x/2i $address_bp" $test { -re ".*$hex :\[^\r\n\]+\r\n\[ \]+($hex).*\.\r\n$gdb_prompt $" { set address_after_bp $expect_out(1,string) pass $test } } if {$address_after_bp == ""} { return } # Write address range where the breakpoint is inserted to the # corresponding variables in the inferior. gdb_test "p /x addr_bp = $address_bp" " = $address_bp" \ "write addr_bp" gdb_test "p /x addr_after_bp = $address_after_bp" " = $address_after_bp" \ "write addr_after_bp" # Run the "setup" function in the inferior. This memcpy's the # breakpoint instruction to a buffer in the inferior. gdb_test "next" "test_basics \\(\\).*" "next over setup" delete_breakpoints # We now have the breakpoint instruction stored in 'buffer'. Poke it # to memory manually. set count [expr $address_after_bp - $address_bp] for {set i 0} {$i < $count} {incr i} { set test "p /x addr_bp\[$i\] = buffer\[$i\]" gdb_test_multiple $test $test { -re "Cannot access memory at address $hex.*$gdb_prompt $" { # Some targets (QEMU for one) will disallow writes to the # .text section under certain circumstances. It is no use # continuing with the test at this point. Just return. unsupported "cannot modify memory" return } -re " = .*$gdb_prompt $" { pass $test } } } } with_test_prefix "basics" { # Run to the permanent breakpoint, just to make sure we've inserted it # correctly. # If the target fails to stop, the remainder of the test will not work # so just return. This can happen on some simulator targets where # the running program doesn't see breakpoints that are visible to # the execution engine, or where writes to the .text section are # quietly ignored. set test "permanent breakpoint causes random signal" gdb_test_multiple "continue" $test { -re "exited normally.*$gdb_prompt $" { unsupported "failed to stop at permanent breakpoint" return } -re "Program received signal SIGTRAP.*$gdb_prompt $" { pass $test } } # Now set a breakpoint on top, thus creating a permanent breakpoint. gdb_breakpoint "$line_bp" # Depending on whether this is a decr_pc_after_break arch, the PC will # be either pointing at the permanent breakpoint address, or just # after. Set the GDB breakpoint on top, and continue, twice. At # least once, GDB will need to step-over the permanent breakpoint. gdb_test "continue" "Breakpoint .*" "stop at permanent breakpoint" gdb_test "p \$prev_counter = counter" " = $decimal" gdb_test "continue" "Breakpoint .*" "stop at permanent breakpoint twice" # Check that indeed the continue made progress, instead of re-trapping # without advancing. gdb_test "p counter - \$prev_counter" " = 1" gdb_test "info breakpoints" \ "breakpoint.*keep.*y.*$hex.*in test at .*$srcfile:$line_bp.*already hit 2 times.*" \ "info breakpoints show enabled breakpoint" gdb_test "disable \$bpnum" gdb_test "commands\nset \$commands_ran = 1\nend" "" \ "set breakpoint commands" gdb_test "info breakpoints" \ "breakpoint.*keep.*n.*$hex.*in test at .*$srcfile:$line_bp.*already hit 2 times.*" \ "info breakpoints shows disabled breakpoint" # Run to the permanent breakpoint again. This time, since it's # disabled, it should act as if we hadn't created it in the first # place. IOW, we should get a random signal, and, the breakpoint's # command should not run. gdb_test "continue" "Program received signal SIGTRAP.*" \ "disabled permanent breakpoint doesn't explain stop" gdb_test "info breakpoints" \ "breakpoint.*keep.*n.*$hex.*in test at .*$srcfile:$line_bp.*already hit 2 times.*" \ "info breakpoints still shows same number of hits" gdb_test "print \$commands_ran" " = void" \ "breakpoint commands didn't run" # Reenable the breakpoint, and check that it gets hit and accounted # for this time. gdb_test "enable \$bpnum" "" "reenable breakpoint" gdb_test "continue" "Breakpoint .*" \ "stop at permanent breakpoint thrice" gdb_test "info breakpoints" \ "breakpoint.*keep.*y.*$hex.*in test at .*$srcfile:$line_bp.*already hit 3 times.*" \ "info breakpoints shows one more hit" gdb_test "print \$commands_ran" " = 1" "breakpoint commands ran" # Check that stepi advances only past the permanent breakpoint, and # not a single instruction more. gdb_test "stepi" "after permanent bp .*" \ "single-step past permanent breakpoint" } with_test_prefix "next trips on permanent bp" { delete_breakpoints gdb_breakpoint "test_next" gdb_continue_to_breakpoint "test_next" gdb_breakpoint "$line_bp" gdb_test "condition \$bpnum 0" gdb_test "next" "after next .*" } if ![target_info exists gdb,nosignals] { with_test_prefix "continue trips on nested permanent bp" { delete_breakpoints gdb_breakpoint "test_signal_nested" gdb_continue_to_breakpoint "test_signal_nested" gdb_breakpoint "$line_bp" gdb_continue_to_breakpoint "permanent bp" gdb_test "condition \$bpnum 0" # Let SIGALRM trigger. sleep 2 # We're now stopped at a permanent breakpoint, with a # signal pending. gdb_breakpoint "test_signal_nested_done" gdb_continue_to_breakpoint "test_signal_nested_done" # Ensure that the handler did run. There's one call to # test in the mainline code, and another in the signal # handler. gdb_test "p counter" " = 2" } if [can_single_step_to_signal_handler] { with_test_prefix "stepi signal with handler" { delete_breakpoints gdb_breakpoint "test_signal_with_handler" gdb_continue_to_breakpoint "test_signal_with_handler" gdb_breakpoint "$line_bp" gdb_test "continue" "Breakpoint .*" "stop at permanent breakpoint" gdb_test "queue-signal SIGUSR1" set test "single-step to handler" gdb_test_multiple "stepi" $test { -re "Program received signal SIGTRAP.*$gdb_prompt $" { fail $test } -re "signal handler called.*$gdb_prompt $" { # After PowerPC Linux kernel commit: # # commit: 0138ba5783ae0dcc799ad401a1e8ac8333790df9 # powerpc/64/signal: Balance return predictor # stack in signal trampoline. # # The kernel places an additional brctl instruction # in the vdso to call the user handler. # # And then this commit: # # commit 24321ac668e452a4942598533d267805f291fdc9 # powerpc/64/signal: Fix regression in # __kernel_sigtramp_rt64() semantics # # updates the semantics of __kernel_sigtramp_rt64(). # It added a new symbol to serve as a jump target from # the kernel to the trampoline. # # The net result of these changes is that gdb stops # at __kernel_start_sigtramp_rt64. Need to do one # more stepi to reach the expected location in the user # signal handler. gdb_test "p \$pc" "__kernel_start_sigtramp_rt64.*" \ "in kernel code" gdb_test "stepi" "handler .*" $test } -re "handler .*$gdb_prompt $" { pass $test } } # Check that the mainline PC points at the permanent # breakpoint. gdb_test "up 2" "test .*" "up to mainline code" gdb_test "p /x \$pc" " = $address_bp" \ "mainline pc points at permanent breakpoint" gdb_test "continue" "Breakpoint .*" \ "stop at permanent breakpoint, out of handler" } with_test_prefix "stepi signal with no handler" { gdb_breakpoint "test_signal_no_handler" gdb_continue_to_breakpoint "test_signal_no_handler" gdb_test "continue" "Breakpoint .*" "stop at permanent breakpoint" gdb_test "queue-signal SIGUSR1" gdb_test "stepi" "after permanent bp .*" \ "single-step past permanent breakpoint" } } } } foreach always_inserted {off on} { foreach sw_watchpoint {0 1} { with_test_prefix "always_inserted=$always_inserted, sw_watchpoint=$sw_watchpoint" { test $always_inserted $sw_watchpoint } } }