@@ -1679,6 +1679,11 @@ for target in $target_list; do
echo "GDB_HAS_MTE=y" >> $config_target_mak
fi
+ if test "${gdb_arches#*aarch64}" != "$gdb_arches" && version_ge $gdb_version 16.0; then
+ # GDB has to support MTE in baremetal to allow debugging MTE in QEMU system mode
+ echo "GDB_SUPPORTS_MTE_IN_BAREMETAL=y" >> $config_target_mak
+ fi
+
echo "run-tcg-tests-$target: $qemu\$(EXESUF)" >> Makefile.prereqs
tcg_tests_targets="$tcg_tests_targets $target"
fi
@@ -2,14 +2,22 @@
# Aarch64 system tests
#
-AARCH64_SYSTEM_SRC=$(SRC_PATH)/tests/tcg/aarch64/system
+AARCH64_SRC=$(SRC_PATH)/tests/tcg/aarch64
+AARCH64_SYSTEM_SRC=$(AARCH64_SRC)/system
+
VPATH+=$(AARCH64_SYSTEM_SRC)
# These objects provide the basic boot code and helper functions for all tests
CRT_OBJS=boot.o
-AARCH64_TEST_SRCS=$(wildcard $(AARCH64_SYSTEM_SRC)/*.c)
-AARCH64_TESTS = $(patsubst $(AARCH64_SYSTEM_SRC)/%.c, %, $(AARCH64_TEST_SRCS))
+AARCH64_TEST_C_SRCS_=$(wildcard $(AARCH64_SYSTEM_SRC)/*.c)
+AARCH64_TEST_S_SRCS=$(AARCH64_SYSTEM_SRC)/mte.S
+
+AARCH64_C_TESTS = $(patsubst $(AARCH64_SYSTEM_SRC)/%.c, %, $(AARCH64_TEST_C_SRCS))
+AARCH64_S_TESTS = $(patsubst $(AARCH64_SYSTEM_SRC)/%.S, %, $(AARCH64_TEST_S_SRCS))
+
+AARCH64_TESTS = $(AARCH64_C_TESTS)
+AARCH64_TESTS += $(AARCH64_S_TESTS)
CRT_PATH=$(AARCH64_SYSTEM_SRC)
LINK_SCRIPT=$(AARCH64_SYSTEM_SRC)/kernel.ld
@@ -21,7 +29,8 @@ LDFLAGS+=-static -nostdlib $(CRT_OBJS) $(MINILIB_OBJS) -lgcc
config-cc.mak: Makefile
$(quiet-@)( \
- $(call cc-option,-march=armv8.3-a, CROSS_CC_HAS_ARMV8_3)) 3> config-cc.mak
+ $(call cc-option,-march=armv8.3-a, CROSS_CC_HAS_ARMV8_3); \
+ $(call cc-option,-march=armv8.5-a+memtag, CROSS_CC_HAS_ARMV8_MTE)) 3> config-cc.mak
-include config-cc.mak
# building head blobs
@@ -88,3 +97,35 @@ pauth-3:
run-pauth-3:
$(call skip-test, "RUN of pauth-3", "not built")
endif
+
+ifneq ($(CROSS_CC_HAS_ARMV8_MTE),)
+QEMU_MTE_ENABLED_MACHINE=-M virt,mte=on -cpu max -display none
+QEMU_OPTS_WITH_MTE_ON = $(QEMU_MTE_ENABLED_MACHINE) $(QEMU_BASE_ARGS) -kernel
+mte: CFLAGS+=-march=armv8.5-a+memtag
+mte: mte.S $(LINK_SCRIPT) $(CRT_OBJS) $(MINILIB_OBJS)
+ $(CC) $(CFLAGS) $(EXTRA_CFLAGS) $< -o $@ $(LDFLAGS)
+
+run-mte: QEMU_OPTS=$(QEMU_OPTS_WITH_MTE_ON)
+run-mte: mte
+
+ifeq ($(GDB_SUPPORTS_MTE_IN_BAREMETAL),y)
+run-gdbstub-mte: QEMU_OPTS=$(QEMU_OPTS_WITH_MTE_ON)
+run-gdbstub-mte: mte
+ $(call run-test, $@, $(GDB_SCRIPT) \
+ --output run-gdbstub-mte.out \
+ --gdb $(GDB) \
+ --qemu $(QEMU) --qargs "-chardev null$(COMMA)id=output $(QEMU_OPTS)" \
+ --bin $< --test $(AARCH64_SRC)/gdbstub/test-mte.py -- --mode=system, \
+ gdbstub MTE support)
+
+EXTRA_RUNS += run-gdbstub-mte
+else # !GDB_SUPPORTS_MTE_IN_BAREMETAL
+run-gdbstub-mte:
+ $(call skip-test "RUN of gdbstub-mte", "GDB does not support MTE in baremetal!")
+endif
+else # !CROSS_CC_HAS_ARMV8_MTE
+mte:
+ $(call skip-test, "BUILD of $@", "missing compiler support")
+run-mte:
+ $(call skip-test, "RUN of mte", "not build")
+endif
@@ -138,7 +138,8 @@ run-gdbstub-mte: mte-8
$(call run-test, $@, $(GDB_SCRIPT) \
--gdb $(GDB) \
--qemu $(QEMU) --qargs "$(QEMU_OPTS)" \
- --bin $< --test $(AARCH64_SRC)/gdbstub/test-mte.py, \
+ --bin $< --test $(AARCH64_SRC)/gdbstub/test-mte.py \
+ -- --mode=user, \
gdbstub MTE support)
EXTRA_RUNS += run-gdbstub-mte
@@ -1,21 +1,26 @@
from __future__ import print_function
#
# Test GDB memory-tag commands that exercise the stubs for the qIsAddressTagged,
-# qMemTag, and QMemTag packets. Logical tag-only commands rely on local
-# operations, hence don't exercise any stub.
+# 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 atag() call (which sets the
-# allocation tag -- see mte-8.c for details) and setting/getting tags in
-# different memory locations and ranges starting at the address of the array
-# 'a'.
+# 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
#
-import gdb
+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 test_gdbstub import main, report
+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]+\\)."
@@ -23,12 +28,32 @@
def run_test():
- gdb.execute("break 95", False, True)
+ 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
- # array 'a' matches the logical tag after atag() is called.
- co = gdb.execute("memory-tag check a", False, True)
+ # 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]}")
@@ -39,20 +64,20 @@ def run_test():
# 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 'a' address to a known value, i.e. 0x04.
- gdb.execute("memory-tag set-allocation-tag a 1 04", False, True)
+ # 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 correct and don't run over each other.
- gdb.execute("memory-tag set-allocation-tag a+16 1 06", False, True)
+ # 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("memory-tag print-allocation-tag a", False, True)
+ co = gdb.execute(f"memory-tag print-allocation-tag {ta}", False, True)
first_tag = re.match(PATTERN_1, co)[1]
- co = gdb.execute("memory-tag print-allocation-tag a+16", False, True)
+ 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":
@@ -61,15 +86,15 @@ def run_test():
report(False, "Can't set/print allocation tags!")
# Now test fill pattern by setting a whole page with a pattern.
- gdb.execute("memory-tag set-allocation-tag a 4096 0a0b", False, True)
+ 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("memory-tag print-allocation-tag a+4096-32", False, True)
+ co = gdb.execute(f"memory-tag print-allocation-tag {ta}+4096-32", False, True)
tag = re.match(PATTERN_1, co)[1]
- co = gdb.execute("memory-tag print-allocation-tag a+4096-16", False, True)
+ 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":
@@ -78,8 +103,8 @@ def run_test():
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.
+ # 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!")
@@ -135,6 +135,17 @@ __start:
orr x1, x1, x3
str x1, [x2] /* 2nd 2mb (.data & .bss)*/
+ /* Third block: .mte_page */
+ adrp x1, .mte_page
+ add x1, x1, :lo12:.mte_page
+ bic x1, x1, #(1 << 21) - 1
+ and x4, x1, x5
+ add x2, x0, x4, lsr #(21 - 3)
+ /* attr(AF, NX, block, AttrIndx=Attr1) */
+ ldr x3, =(3 << 53) | 0x401 | (1 << 2)
+ orr x1, x1, x3
+ str x1, [x2]
+
/* Setup/enable the MMU. */
/*
@@ -239,3 +250,6 @@ ttb_stage2:
stack:
.space 65536, 0
stack_end:
+
+ /* .mte_page location is set in kernel.ld. */
+ .section .mte_page
@@ -18,6 +18,11 @@ SECTIONS
.bss : {
*(.bss)
}
+ /* align MTE section to next (third) 2mb */
+ . = ALIGN(1 << 22);
+ .mte : {
+ *(.mte_page)
+ }
/DISCARD/ : {
*(.ARM.attributes)
}
new file mode 100644
@@ -0,0 +1,115 @@
+/*
+ * Code to help test the MTE gdbstubs in system mode.
+ *
+ * Copyright (c) 2024 Linaro Limited
+ *
+ * Author: Gustavo Romero <gustavo.romero@linaro.org>
+ *
+ * SPDX-License-Identifier: LGPL-2.1-or-later
+ */
+
+#define addr x0 /* Ptr to the start of the MTE-enabled page. */
+#define tagged_addr x1 /* 'addr' ptr with a random-generated tag added. */
+#define tmp0 x2 /* Scratch register. */
+#define tmp1 x3 /* Scratch register. */
+#define tmp2 x4 /* Scratch register. */
+#define tmp3 x5 /* Sctatch register. */
+
+ .file "mte.S"
+
+ .text
+ .align 4
+
+ .globl main
+ .type main, @function
+
+main:
+ /*
+ * Set MAIR_EL1 (Memory Attribute Index Register). In boot.S, the
+ * attribute index for .mte_page is set to point to MAILR_EL field Attr1
+ * (AttrIndx=Attr1), so set Attr1 as Tagged Normal (MTE) to enable MTE
+ * on this page.
+ *
+ * Attr1 = 0xF0 => Tagged Normal (MTE)
+ */
+ mrs tmp0, mair_el1
+ orr tmp0, tmp0, (0xF0 << 8)
+ msr mair_el1, tmp0
+
+ /*
+ * Set TCR_EL1 (Translation Control Registers) to ignore the top byte
+ * in the translated addresses so it can be used to keep the tags.
+ *
+ * TBI0[37] = 0b1 => Top Byte ignored and used for tagged addresses
+ */
+ mrs tmp1, tcr_el1
+ orr tmp1, tmp1, (1 << 37)
+ msr tcr_el1, tmp1
+
+ /*
+ * Set SCTLR_EL1 (System Control Register) to enable the use of MTE
+ * insns., like stg & friends, and to enable synchronous exception in
+ * case of a tag mismatch, i.e., when the logical tag in 'tagged_addr'
+ * is different from the allocation tag related to 'addr' address.
+ *
+ * ATA[43] = 0b1 => Enable access to allocation tags at EL1
+ * TCF[41:40] = 0b01 => Tag Check Faults cause a synchronous exception
+ *
+ */
+ mrs tmp2, sctlr_el1
+ mov tmp3, (1 << 43) | (1 << 40)
+ orr tmp2, tmp2, tmp3
+ msr sctlr_el1, tmp2
+
+ isb
+
+ /*
+ * MTE-enabled page resides at the 3rd 2MB chunk in the second 1GB
+ * block, i.e., at 0x40400000 address. See .mte_page section in boot.S
+ * and kernel.ld (where the address is effectively computed).
+ *
+ * Load .mte_page address into 'addr' register.
+ */
+ adrp addr, .mte_page
+ add addr, addr, :lo12:.mte_page
+
+ /*
+ * Set GCR for random tag generation. 0xA5 is just a random value to set
+ * GCR != 0 so the tag generated by 'irg' insn. is not zero, which is
+ * more interesting for the tests than when tag is zero.
+ */
+ mov tmp0, 0xA5
+ msr gcr_el1, tmp0
+
+ /*
+ * Generate a logical tag, add it to 'addr' address and put it into
+ * 'tagged_addr'.
+ */
+ irg tagged_addr, addr
+
+ /*
+ * Store the generated tag to memory region pointed to by 'addr', i.e.
+ * set the allocation tag for granule at 'addr'. The tag is extracted
+ * by stg from tagged_addr pointer.
+ */
+ stg tagged_addr, [addr]
+
+ /*
+ * Store a random value (0xdeadbeef) to tagged_addr address. This must
+ * not cause any Tag Check Fault since logical tag in tagged_addr and
+ * allocation tag associated with the memory pointed by tagged_addr are
+ * set the same, otherwise something is off and the test fails -- an
+ * exception is generated.
+ */
+ ldr tmp1, =0xdeadbeef
+ str tmp1, [tagged_addr]
+
+ /* This label is used by GDB Python script test-mte.py. */
+main_end:
+ ret
+
+ /*
+ * See boot.S for details on the attributes set for this page and
+ * kernel.ld for where its location in memory is set.
+ */
+ .section .mte_page
Extend MTE gdbstub tests to also run in system mode (share tests between user mode and system mode). The tests will only run if a version of GDB that supports MTE on baremetal is available in the test environment and if available compiler supports the 'memtag' flag (-march=armv8.5-a+memtag). For the tests running in system mode, a page that supports MTE ops. is necessary. Therefore, an MTE-enabled page is made available (mapped) in the third 2 MB chunk of the second 1 GB space in the flat mapping set in boot.S. A new binary, mte.S, is also introduced for the tests. It links against boot.S and is executed by QEMU in system mode. Signed-off-by: Gustavo Romero <gustavo.romero@linaro.org> --- configure | 5 + tests/tcg/aarch64/Makefile.softmmu-target | 49 ++++++++- tests/tcg/aarch64/Makefile.target | 3 +- tests/tcg/aarch64/gdbstub/test-mte.py | 71 ++++++++----- tests/tcg/aarch64/system/boot.S | 14 +++ tests/tcg/aarch64/system/kernel.ld | 5 + tests/tcg/aarch64/system/mte.S | 115 ++++++++++++++++++++++ 7 files changed, 234 insertions(+), 28 deletions(-) create mode 100644 tests/tcg/aarch64/system/mte.S