gdb/testsuite/gdb.arch/amd64-disp-step-avx.exp - binutils-gdb - Git at Google

 # Copyright 2009-2021 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 <http://www.gnu.org/licenses/>.

 # This file is part of the gdb testsuite.

 # Test displaced stepping over VEX-encoded RIP-relative AVX
 # instructions.

 if { ![istarget x86_64-*-* ] || ![is_lp64_target] } {
     verbose "Skipping x86_64 displaced stepping tests."
     return
 }

 if { ![have_avx] } {
     verbose "Skipping x86_64 displaced stepping tests."
     return
 }

 standard_testfile .S

 set options [list debug \
 		 additional_flags=-static \
 		 additional_flags=-nostartfiles]
 if { [prepare_for_testing "failed to prepare" ${testfile} ${srcfile} $options] } {
     return -1
 }

 # Get things started.

 gdb_test "set displaced-stepping on" ""
 gdb_test "show displaced-stepping" ".* displaced stepping .* is on.*"

 if ![runto_main] then {
     return 0
 }

 # GDB picks a spare register from this list to hold the RIP-relative
 # address.
 set rip_regs { "rax" "rbx" "rcx" "rdx" "rbp" "rsi" "rdi" }

 # Assign VAL to all the RIP_REGS.

 proc set_regs { val } {
     global gdb_prompt
     global rip_regs

     foreach reg ${rip_regs} {
 	gdb_test_no_output "set \$${reg} = ${val}"
     }
 }

 # Verify all RIP_REGS print as HEX_VAL_RE in hex.

 proc verify_regs { hex_val_re } {
     global rip_regs

     foreach reg ${rip_regs} {
 	gdb_test "p /x \$${reg}" " = ${hex_val_re}" "${reg} expected value"
     }
 }

 # Set a break at FUNC, which starts with a RIP-relative instruction
 # that we want to displaced-step over, and then continue over the
 # breakpoint, forcing a displaced-stepping sequence.

 proc disp_step_func { func } {
     global srcfile

     set test_start_label "${func}"
     set test_end_label "${func}_end"

     gdb_test "break ${test_start_label}" \
 	"Breakpoint.*at.* file .*$srcfile, line.*"
     gdb_test "break ${test_end_label}" \
 	"Breakpoint.*at.* file .*$srcfile, line.*"

     gdb_test "continue" \
 	"Continuing.*Breakpoint.*, ${test_start_label} ().*" \
 	"continue to ${test_start_label}"

     # GDB picks a spare register to hold the RIP-relative address.
     # Ensure the spare register value is restored properly (rax-rdi,
     # sans rsp).
     set value "0xdeadbeefd3adb33f"
     set_regs $value

     # Turn "debug displaced" on to make sure a displaced step is actually
     # executed, not an inline step.
     gdb_test_no_output "set debug displaced on"

     gdb_test "continue" \
 	"Continuing.*prepared successfully .*Breakpoint.*, ${test_end_label} ().*" \
 	"continue to ${test_end_label}"

     gdb_test_no_output "set debug displaced off"

     verify_regs $value
 }

 # Test a VEX2-encoded RIP-relative instruction.
 with_test_prefix "vex2" {
     # This test writes to the 'xmm0' register.  As the test is
     # statically linked, we know that the XMM registers should all
     # have the default value of 0 at this point in time.  We're about
     # to run an AVX instruction that will modify $xmm0, but lets first
     # confirm that all XMM registers are 0.
     for {set i 0 } { $i < 16 } { incr i } {
 	gdb_test "p /x \$xmm${i}.uint128" " = 0x0" \
 	    "xmm${i} has expected value before"
     }

     disp_step_func "test_rip_vex2"

     # Confirm the instruction's expected side effects.  It should have
     # modified xmm0.
     gdb_test "p /x \$xmm0.uint128" " = 0x1122334455667788" \
 	"xmm0 has expected value after"

     # And all of the other XMM register should still be 0.
     for {set i 1 } { $i < 16 } { incr i } {
 	gdb_test "p /x \$xmm${i}.uint128" " = 0x0" \
 	    "xmm${i} has expected value after"
     }
 }

 # Test a VEX3-encoded RIP-relative instruction.
 with_test_prefix "vex3" {
     # This case writes to the 'var128' variable.  Confirm the
     # variable's value is what we believe it is before the AVX
     # instruction runs.
     gdb_test "p /x (unsigned long long \[2\]) var128" \
 	" = \\{0xaa55aa55aa55aa55, 0x55aa55aa55aa55aa\\}" \
 	"var128 has expected value before"

     # Run the AVX instruction.
     disp_step_func "test_rip_vex3"

     # Confirm the instruction's expected side effects.  It should have
     # modifed the 'var128' variable.
     gdb_test "p /x (unsigned long long \[2\]) var128" \
 	" = \\{0x1122334455667788, 0x0\\}" \
 	"var128 has expected value after"
 }

 # Done, run program to exit.
 gdb_continue_to_end "amd64-disp-step-avx"
	# Copyright 2009-2021 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 <http://www.gnu.org/licenses/>.

	# This file is part of the gdb testsuite.

	# Test displaced stepping over VEX-encoded RIP-relative AVX
	# instructions.

	if { ![istarget x86_64-- ] \|\| ![is_lp64_target] } {
	verbose "Skipping x86_64 displaced stepping tests."
	return
	}

	if { ![have_avx] } {
	verbose "Skipping x86_64 displaced stepping tests."
	return
	}

	standard_testfile .S

	set options [list debug \
	additional_flags=-static \
	additional_flags=-nostartfiles]
	if { [prepare_for_testing "failed to prepare" ${testfile} ${srcfile} $options] } {
	return -1
	}

	# Get things started.

	gdb_test "set displaced-stepping on" ""
	gdb_test "show displaced-stepping" ".* displaced stepping .* is on.*"

	if ![runto_main] then {
	return 0
	}

	# GDB picks a spare register from this list to hold the RIP-relative
	# address.
	set rip_regs { "rax" "rbx" "rcx" "rdx" "rbp" "rsi" "rdi" }

	# Assign VAL to all the RIP_REGS.

	proc set_regs { val } {
	global gdb_prompt
	global rip_regs

	foreach reg ${rip_regs} {
	gdb_test_no_output "set \$${reg} = ${val}"
	}
	}

	# Verify all RIP_REGS print as HEX_VAL_RE in hex.

	proc verify_regs { hex_val_re } {
	global rip_regs

	foreach reg ${rip_regs} {
	gdb_test "p /x \$${reg}" " = ${hex_val_re}" "${reg} expected value"
	}
	}

	# Set a break at FUNC, which starts with a RIP-relative instruction
	# that we want to displaced-step over, and then continue over the
	# breakpoint, forcing a displaced-stepping sequence.

	proc disp_step_func { func } {
	global srcfile

	set test_start_label "${func}"
	set test_end_label "${func}_end"

	gdb_test "break ${test_start_label}" \
	"Breakpoint.at. file .$srcfile, line."
	gdb_test "break ${test_end_label}" \
	"Breakpoint.at. file .$srcfile, line."

	gdb_test "continue" \
	"Continuing.Breakpoint., ${test_start_label} ().*" \
	"continue to ${test_start_label}"

	# GDB picks a spare register to hold the RIP-relative address.
	# Ensure the spare register value is restored properly (rax-rdi,
	# sans rsp).
	set value "0xdeadbeefd3adb33f"
	set_regs $value

	# Turn "debug displaced" on to make sure a displaced step is actually
	# executed, not an inline step.
	gdb_test_no_output "set debug displaced on"

	gdb_test "continue" \
	"Continuing.prepared successfully .Breakpoint., ${test_end_label} ()." \
	"continue to ${test_end_label}"

	gdb_test_no_output "set debug displaced off"

	verify_regs $value
	}

	# Test a VEX2-encoded RIP-relative instruction.
	with_test_prefix "vex2" {
	# This test writes to the 'xmm0' register. As the test is
	# statically linked, we know that the XMM registers should all
	# have the default value of 0 at this point in time. We're about
	# to run an AVX instruction that will modify $xmm0, but lets first
	# confirm that all XMM registers are 0.
	for {set i 0 } { $i < 16 } { incr i } {
	gdb_test "p /x \$xmm${i}.uint128" " = 0x0" \
	"xmm${i} has expected value before"
	}

	disp_step_func "test_rip_vex2"

	# Confirm the instruction's expected side effects. It should have
	# modified xmm0.
	gdb_test "p /x \$xmm0.uint128" " = 0x1122334455667788" \
	"xmm0 has expected value after"

	# And all of the other XMM register should still be 0.
	for {set i 1 } { $i < 16 } { incr i } {
	gdb_test "p /x \$xmm${i}.uint128" " = 0x0" \
	"xmm${i} has expected value after"
	}
	}

	# Test a VEX3-encoded RIP-relative instruction.
	with_test_prefix "vex3" {
	# This case writes to the 'var128' variable. Confirm the
	# variable's value is what we believe it is before the AVX
	# instruction runs.
	gdb_test "p /x (unsigned long long \[2\]) var128" \
	" = \\{0xaa55aa55aa55aa55, 0x55aa55aa55aa55aa\\}" \
	"var128 has expected value before"

	# Run the AVX instruction.
	disp_step_func "test_rip_vex3"

	# Confirm the instruction's expected side effects. It should have
	# modifed the 'var128' variable.
	gdb_test "p /x (unsigned long long \[2\]) var128" \
	" = \\{0x1122334455667788, 0x0\\}" \
	"var128 has expected value after"
	}

	# Done, run program to exit.
	gdb_continue_to_end "amd64-disp-step-avx"