# Copyright 2014-2020 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 . # Test alternating between watchpoint types, watching a sliding window # of addresses (thus alternating between aligned and unaligned # addresses). Only a single watchpoint exists at any given time. On # targets that only update the debug registers on resume, this # stresses the debug register setup code, both in GDB and in the # target/kernel as one watchpoint replaces the other in a single # operation. (Note that we don't have any of these watchpoints # trigger.) standard_testfile if {[prepare_for_testing "failed to prepare" $testfile $srcfile debug]} { return -1 } if ![runto_main] then { fail "can't run to main" return 0 } # The line we'll be stepping. set srcline [gdb_get_line_number "stepi line"] # The address the program is stopped at currently. set cur_addr "" # Get the current PC. proc get_pc {} { global hex gdb_prompt set addr "" set test "get PC" gdb_test_multiple "p /x \$pc" "$test" { -re " = ($hex).*$gdb_prompt $" { set addr $expect_out(1,string) pass "$test" } } return $addr } # Issue a stepi, and make sure the program advanced past the current # instruction (stored in the CUR_ADDR global). proc stepi {} { global hex gdb_prompt cur_addr set srcline " for (i = 0; i < 100000; i++); /* stepi line */" set test "stepi advanced" gdb_test_multiple "stepi" $test { -re -wrap "[string_to_regexp $srcline]" { set addr [get_valueof "/x" "\$pc" "0"] if {$addr != $cur_addr} { pass $test } else { fail $test } set cur_addr $addr } } } gdb_breakpoint $srcline gdb_continue_to_breakpoint "stepi line" set cur_addr [get_pc] # The test tries various sequences of different types of watchpoints. # Probe for support first. proc build_cmds_list {} { global gdb_prompt # So we get an immediate warning/error if the target doesn't support a # given watchpoint type. gdb_test_no_output "set breakpoint always-inserted on" \ "Set breakpoints always inserted while building cmds list" # The list of supported commands. Below we'll probe for support and # add elements to this list. set cmds {} foreach cmd {"watch" "awatch" "rwatch"} { set test $cmd gdb_test_multiple "$cmd buf.byte\[0\]" $test { -re "You may have requested too many.*$gdb_prompt $" { unsupported $test } -re "Target does not support.*$gdb_prompt $" { unsupported $test } -re "Can't set read/access watchpoint when hardware watchpoints are disabled.*$gdb_prompt $" { unsupported $test } -re "$gdb_prompt $" { pass $test lappend cmds $cmd } } delete_breakpoints } set test "hbreak" gdb_test_multiple "hbreak -q main" $test { -re "You may have requested too many.*$gdb_prompt $" { unsupported $test } -re "No hardware breakpoint support.*$gdb_prompt $" { unsupported $test } -re "$gdb_prompt $" { pass $test lappend cmds "hbreak" } } delete_breakpoints return $cmds } # Return true if the memory range [buf.byte + OFFSET, +WIDTH] can be # monitored by CMD, otherwise return false. proc valid_addr_p {cmd offset width} { if { [istarget "aarch64*-*-linux*"] } { # The aarch64 Linux kernel port only accepts 4-byte aligned addresses # for hardware breakpoints and 8-byte aligned addresses for hardware # watchpoints. However, both GDB and GDBserver support unaligned # watchpoints by using more than one properly aligned watchpoint # registers to represent the whole unaligned region. Breakpoint # addresses must still be aligned though. if {$cmd == "hbreak" } { if { [expr ($offset) % 4] != 0 } { return 0 } } } elseif { [istarget "arm*-*-linux*"] } { if { $cmd == "hbreak" } { # Breakpoints must be of length 2 (thumb) or 4 (ARM) bytes. if { $width != 2 && $width != 4 } { return 0 } } else { # Watchpoints can be of length 1, 2, 4 or 8 bytes. if { [expr $width % 2] != 0 } { return 0 } } if { [expr ($offset) % 8] == 0 && $width == 8 } { # If WIDTH is 8 byte, the address should be 8-byte aligned. return 1 } elseif { [expr ($offset) % 4] == 0 } { return 1 } elseif { [expr ($offset) % 4] == 2 && $width == 2 } { # Halfword watchpoints and breakpoints. return 1 } elseif { [expr ($offset) % 4] == 1 && $width == 1 && $cmd != "hbreak" } { # Single byte watchpoints. return 1 } else { return 0 } } return 1 } # Watch WIDTH bytes at BASE + OFFSET. CMD specifices the specific # type of watchpoint to use. If CMD is "hbreak", WIDTH is ignored. # The HW_WP_P flag tells us if hardware watchpoints are enabled or # not. proc watch_command {cmd base offset width hw_wp_p} { global srcfile srcline hex if {$cmd == "hbreak"} { set expr "*(buf.byte + $base + $offset)" gdb_test "hbreak $expr" "Hardware assisted breakpoint \[0-9\]+ at $hex" } elseif {$cmd == "watch"} { set expr "*(buf.byte + $base + $offset)@$width" if { ! $hw_wp_p } { set wp_prefix "Watchpoint" } else { set wp_prefix "Hardware watchpoint" } gdb_test "$cmd $expr" \ "${wp_prefix} \[0-9\]+: [string_to_regexp $expr]" } elseif {$cmd == "awatch"} { set expr "*(buf.byte + $base + $offset)@$width" gdb_test "$cmd $expr" \ "Hardware access \\(read/write\\) watchpoint \[0-9\]+: [string_to_regexp $expr]" } elseif {$cmd == "rwatch"} { set expr "*(buf.byte + $base + $offset)@$width" gdb_test "$cmd $expr" \ "Hardware read watchpoint \[0-9\]+: [string_to_regexp $expr]" } } # Run the watchpoint tests (see the description at the top for details), the # HW_WP_P flag tells us if hardware watchpoints are enabled or not. proc run_watchpoints_tests {hw_wp_p} { set cmds [build_cmds_list] foreach always_inserted {"off" "on" } { gdb_test_no_output "set breakpoint always-inserted $always_inserted" foreach cmd1 $cmds { foreach cmd2 $cmds { for {set width 1} {$width < 4} {incr width} { if {$cmd1 == "hbreak" && $cmd2 == "hbreak" \ && $width > 1} { # hbreak ignores WIDTH, no use testing more than # once. continue } for {set x 0} {$x < 4} {incr x} { if { ![valid_addr_p $cmd1 $x $width] || ![valid_addr_p $cmd2 $x+1 $width] } { # Skip tests if requested address or length # of breakpoint or watchpoint don't meet # target or kernel requirements. continue } set prefix "always-inserted $always_inserted: " append prefix "$cmd1 x $cmd2: " with_test_prefix "$prefix: width $width, iter $x" { with_test_prefix "base + 0" { watch_command $cmd1 $x 0 $width $hw_wp_p stepi gdb_test_no_output "delete \$bpnum" } with_test_prefix "base + 1" { watch_command $cmd2 $x 1 $width $hw_wp_p stepi gdb_test_no_output "delete \$bpnum" } } } } } } } } # Based on HW_WP_P set whether hardware watchpoints can be used or # not, then call RUN_WATCHPOINTS_TESTS. proc setup_and_run_watchpoints_tests { hw_wp_p } { if {$hw_wp_p} { set prefix "hw-watch" } else { set prefix "sw-watch" } with_test_prefix $prefix { gdb_test_no_output "set can-use-hw-watchpoints ${hw_wp_p}" run_watchpoints_tests $hw_wp_p } } # Run tests with hardware watchpoints disabled, then again with them # enabled (if this target supports hardware watchpoints). if { ![target_info exists gdb,no_hardware_watchpoints]} { # Run test with H/W enabled. setup_and_run_watchpoints_tests 1 } # Run test with H/W disabled setup_and_run_watchpoints_tests 0