blob: a4cae6caa0a21aec50fa1bc71026c62ca1231705 [file] [log] [blame]
from __future__ import print_function
#
# Test GDB memory-tag commands that exercise the stubs for the qIsAddressTagged,
# qMemTag, and QMemTag packets, which are used for manipulating allocation tags.
# Logical tags-related commands rely on local operations, hence don't exercise
# any stub and so are not used in this test.
#
# The test consists in breaking just after a tag is set in a specific memory
# chunk, and then using the GDB 'memory-tagging' subcommands to set/get tags in
# different memory locations and ranges in the MTE-enabled memory chunk.
#
# This is launched via tests/guest-debug/run-test.py
#
try:
import gdb
except ModuleNotFoundError:
from sys import exit
exit("This script must be launched via tests/guest-debug/run-test.py!")
import re
from sys import argv
from test_gdbstub import arg_parser, main, report
PATTERN_0 = "Memory tags for address 0x[0-9a-f]+ match \\(0x[0-9a-f]+\\)."
PATTERN_1 = ".*(0x[0-9a-f]+)"
def run_test():
p = arg_parser(prog="test-mte.py", description="TCG MTE tests.")
p.add_argument("--mode", help="Run test for QEMU system or user mode.",
required=True, choices=['system','user'])
args = p.parse_args(args=argv)
if args.mode == "system":
# Break address: where to break before performing the tests
# See mte.S for details about this label.
ba = "main_end"
# Tagged address: the start of the MTE-enabled memory chunk to be tested
# 'tagged_addr' (x1) is a pointer to the MTE-enabled page. See mte.S.
ta = "$x1"
else: # mode="user"
# Line 95 in mte-8.c
ba = "95"
# 'a' array. See mte-8.c
ta = "a"
gdb.execute(f"break {ba}", False, True)
gdb.execute("continue", False, True)
try:
# Test if we can check correctly that the allocation tag for the address
# in {ta} matches the logical tag in {ta}.
co = gdb.execute(f"memory-tag check {ta}", False, True)
tags_match = re.findall(PATTERN_0, co, re.MULTILINE)
if tags_match:
report(True, f"{tags_match[0]}")
else:
report(False, "Logical and allocation tags don't match!")
# Test allocation tag 'set and print' commands. Commands on logical
# tags rely on local operation and so don't exercise any stub.
# Set the allocation tag for the first granule (16 bytes) of
# address starting at {ta} address to a known value, i.e. 0x04.
gdb.execute(f"memory-tag set-allocation-tag {ta} 1 04", False, True)
# Then set the allocation tag for the second granule to a known
# value, i.e. 0x06. This tests that contiguous tag granules are
# set correctly and don't run over each other.
gdb.execute(f"memory-tag set-allocation-tag {ta}+16 1 06", False, True)
# Read the known values back and check if they remain the same.
co = gdb.execute(f"memory-tag print-allocation-tag {ta}", False, True)
first_tag = re.match(PATTERN_1, co)[1]
co = gdb.execute(f"memory-tag print-allocation-tag {ta}+16", False, True)
second_tag = re.match(PATTERN_1, co)[1]
if first_tag == "0x4" and second_tag == "0x6":
report(True, "Allocation tags are correctly set/printed.")
else:
report(False, "Can't set/print allocation tags!")
# Now test fill pattern by setting a whole page with a pattern.
gdb.execute(f"memory-tag set-allocation-tag {ta} 4096 0a0b", False, True)
# And read back the tags of the last two granules in page so
# we also test if the pattern is set correctly up to the end of
# the page.
co = gdb.execute(f"memory-tag print-allocation-tag {ta}+4096-32", False, True)
tag = re.match(PATTERN_1, co)[1]
co = gdb.execute(f"memory-tag print-allocation-tag {ta}+4096-16", False, True)
last_tag = re.match(PATTERN_1, co)[1]
if tag == "0xa" and last_tag == "0xb":
report(True, "Fill pattern is ok.")
else:
report(False, "Fill pattern failed!")
except gdb.error:
# This usually happens because a GDB version that does not support
# memory tagging was used to run the test.
report(False, "'memory-tag' command failed!")
main(run_test, expected_arch="aarch64")