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- // SPDX-License-Identifier: GPL-2.0
- #define _GNU_SOURCE
- #include <elf.h>
- #include <pthread.h>
- #include <stdbool.h>
- #include <asm/prctl.h>
- #include <sys/ptrace.h>
- #include <sys/syscall.h>
- #include <sys/uio.h>
- #include <sys/wait.h>
- #include "helpers.h"
- #include "xstate.h"
- /*
- * The userspace xstate test suite is designed to be generic and operates
- * with randomized xstate data. However, some states require special handling:
- *
- * - PKRU and XTILECFG need specific adjustments, such as modifying
- * randomization behavior or using fixed values.
- * - But, PKRU already has a dedicated test suite in /tools/selftests/mm.
- * - Legacy states (FP and SSE) are excluded, as they are not considered
- * part of extended states (xstates) and their usage is already deeply
- * integrated into user-space libraries.
- */
- #define XFEATURE_MASK_TEST_SUPPORTED \
- ((1 << XFEATURE_YMM) | \
- (1 << XFEATURE_OPMASK) | \
- (1 << XFEATURE_ZMM_Hi256) | \
- (1 << XFEATURE_Hi16_ZMM) | \
- (1 << XFEATURE_XTILEDATA) | \
- (1 << XFEATURE_APX))
- static inline uint64_t xgetbv(uint32_t index)
- {
- uint32_t eax, edx;
- asm volatile("xgetbv" : "=a" (eax), "=d" (edx) : "c" (index));
- return eax + ((uint64_t)edx << 32);
- }
- static inline uint64_t get_xstatebv(struct xsave_buffer *xbuf)
- {
- return *(uint64_t *)(&xbuf->header);
- }
- static struct xstate_info xstate;
- struct futex_info {
- unsigned int iterations;
- struct futex_info *next;
- pthread_mutex_t mutex;
- pthread_t thread;
- bool valid;
- int nr;
- };
- static inline void load_rand_xstate(struct xstate_info *xstate, struct xsave_buffer *xbuf)
- {
- clear_xstate_header(xbuf);
- set_xstatebv(xbuf, xstate->mask);
- set_rand_data(xstate, xbuf);
- xrstor(xbuf, xstate->mask);
- }
- static inline void load_init_xstate(struct xstate_info *xstate, struct xsave_buffer *xbuf)
- {
- clear_xstate_header(xbuf);
- xrstor(xbuf, xstate->mask);
- }
- static inline void copy_xstate(struct xsave_buffer *xbuf_dst, struct xsave_buffer *xbuf_src)
- {
- memcpy(&xbuf_dst->bytes[xstate.xbuf_offset],
- &xbuf_src->bytes[xstate.xbuf_offset],
- xstate.size);
- }
- static inline bool validate_xstate_same(struct xsave_buffer *xbuf1, struct xsave_buffer *xbuf2)
- {
- int ret;
- ret = memcmp(&xbuf1->bytes[xstate.xbuf_offset],
- &xbuf2->bytes[xstate.xbuf_offset],
- xstate.size);
- return ret == 0;
- }
- static inline bool validate_xregs_same(struct xsave_buffer *xbuf1)
- {
- struct xsave_buffer *xbuf2;
- bool ret;
- xbuf2 = alloc_xbuf();
- if (!xbuf2)
- ksft_exit_fail_msg("failed to allocate XSAVE buffer\n");
- xsave(xbuf2, xstate.mask);
- ret = validate_xstate_same(xbuf1, xbuf2);
- free(xbuf2);
- return ret;
- }
- /* Context switching test */
- static void *check_xstate(void *info)
- {
- struct futex_info *finfo = (struct futex_info *)info;
- struct xsave_buffer *xbuf;
- int i;
- xbuf = alloc_xbuf();
- if (!xbuf)
- ksft_exit_fail_msg("unable to allocate XSAVE buffer\n");
- /*
- * Load random data into 'xbuf' and then restore it to the xstate
- * registers.
- */
- load_rand_xstate(&xstate, xbuf);
- finfo->valid = true;
- for (i = 0; i < finfo->iterations; i++) {
- pthread_mutex_lock(&finfo->mutex);
- /*
- * Ensure the register values have not diverged from the
- * record. Then reload a new random value. If it failed
- * ever before, skip it.
- */
- if (finfo->valid) {
- finfo->valid = validate_xregs_same(xbuf);
- load_rand_xstate(&xstate, xbuf);
- }
- /*
- * The last thread's last unlock will be for thread 0's
- * mutex. However, thread 0 will have already exited the
- * loop and the mutex will already be unlocked.
- *
- * Because this is not an ERRORCHECK mutex, that
- * inconsistency will be silently ignored.
- */
- pthread_mutex_unlock(&finfo->next->mutex);
- }
- free(xbuf);
- return finfo;
- }
- static void create_threads(uint32_t num_threads, uint32_t iterations, struct futex_info *finfo)
- {
- int i;
- for (i = 0; i < num_threads; i++) {
- int next_nr;
- finfo[i].nr = i;
- finfo[i].iterations = iterations;
- /*
- * Thread 'i' will wait on this mutex to be unlocked.
- * Lock it immediately after initialization:
- */
- pthread_mutex_init(&finfo[i].mutex, NULL);
- pthread_mutex_lock(&finfo[i].mutex);
- next_nr = (i + 1) % num_threads;
- finfo[i].next = &finfo[next_nr];
- if (pthread_create(&finfo[i].thread, NULL, check_xstate, &finfo[i]))
- ksft_exit_fail_msg("pthread_create() failed\n");
- }
- }
- static bool checkout_threads(uint32_t num_threads, struct futex_info *finfo)
- {
- void *thread_retval;
- bool valid = true;
- int err, i;
- for (i = 0; i < num_threads; i++) {
- err = pthread_join(finfo[i].thread, &thread_retval);
- if (err)
- ksft_exit_fail_msg("pthread_join() failed for thread %d err: %d\n", i, err);
- if (thread_retval != &finfo[i]) {
- ksft_exit_fail_msg("unexpected thread retval for thread %d: %p\n",
- i, thread_retval);
- }
- valid &= finfo[i].valid;
- }
- return valid;
- }
- static void affinitize_cpu0(void)
- {
- cpu_set_t cpuset;
- CPU_ZERO(&cpuset);
- CPU_SET(0, &cpuset);
- if (sched_setaffinity(0, sizeof(cpuset), &cpuset) != 0)
- ksft_exit_fail_msg("sched_setaffinity to CPU 0 failed\n");
- }
- static void test_context_switch(uint32_t num_threads, uint32_t iterations)
- {
- struct futex_info *finfo;
- /* Affinitize to one CPU to force context switches */
- affinitize_cpu0();
- printf("[RUN]\t%s: check context switches, %d iterations, %d threads.\n",
- xstate.name, iterations, num_threads);
- finfo = malloc(sizeof(*finfo) * num_threads);
- if (!finfo)
- ksft_exit_fail_msg("unable allocate memory\n");
- create_threads(num_threads, iterations, finfo);
- /*
- * This thread wakes up thread 0
- * Thread 0 will wake up 1
- * Thread 1 will wake up 2
- * ...
- * The last thread will wake up 0
- *
- * This will repeat for the configured
- * number of iterations.
- */
- pthread_mutex_unlock(&finfo[0].mutex);
- /* Wait for all the threads to finish: */
- if (checkout_threads(num_threads, finfo))
- printf("[OK]\tNo incorrect case was found.\n");
- else
- printf("[FAIL]\tFailed with context switching test.\n");
- free(finfo);
- }
- /*
- * Ptrace test for the ABI format as described in arch/x86/include/asm/user.h
- */
- /*
- * Make sure the ptracee has the expanded kernel buffer on the first use.
- * Then, initialize the state before performing the state injection from
- * the ptracer. For non-dynamic states, this is benign.
- */
- static inline void ptracee_touch_xstate(void)
- {
- struct xsave_buffer *xbuf;
- xbuf = alloc_xbuf();
- load_rand_xstate(&xstate, xbuf);
- load_init_xstate(&xstate, xbuf);
- free(xbuf);
- }
- /*
- * Ptracer injects the randomized xstate data. It also reads before and
- * after that, which will execute the kernel's state copy functions.
- */
- static void ptracer_inject_xstate(pid_t target)
- {
- uint32_t xbuf_size = get_xbuf_size();
- struct xsave_buffer *xbuf1, *xbuf2;
- struct iovec iov;
- /*
- * Allocate buffers to keep data while ptracer can write the
- * other buffer
- */
- xbuf1 = alloc_xbuf();
- xbuf2 = alloc_xbuf();
- if (!xbuf1 || !xbuf2)
- ksft_exit_fail_msg("unable to allocate XSAVE buffer\n");
- iov.iov_base = xbuf1;
- iov.iov_len = xbuf_size;
- if (ptrace(PTRACE_GETREGSET, target, (uint32_t)NT_X86_XSTATE, &iov))
- ksft_exit_fail_msg("PTRACE_GETREGSET failed\n");
- printf("[RUN]\t%s: inject xstate via ptrace().\n", xstate.name);
- load_rand_xstate(&xstate, xbuf1);
- copy_xstate(xbuf2, xbuf1);
- if (ptrace(PTRACE_SETREGSET, target, (uint32_t)NT_X86_XSTATE, &iov))
- ksft_exit_fail_msg("PTRACE_SETREGSET failed\n");
- if (ptrace(PTRACE_GETREGSET, target, (uint32_t)NT_X86_XSTATE, &iov))
- ksft_exit_fail_msg("PTRACE_GETREGSET failed\n");
- if (*(uint64_t *)get_fpx_sw_bytes(xbuf1) == xgetbv(0))
- printf("[OK]\t'xfeatures' in SW reserved area was correctly written\n");
- else
- printf("[FAIL]\t'xfeatures' in SW reserved area was not correctly written\n");
- if (validate_xstate_same(xbuf2, xbuf1))
- printf("[OK]\txstate was correctly updated.\n");
- else
- printf("[FAIL]\txstate was not correctly updated.\n");
- free(xbuf1);
- free(xbuf2);
- }
- static void test_ptrace(void)
- {
- pid_t child;
- int status;
- child = fork();
- if (child < 0) {
- ksft_exit_fail_msg("fork() failed\n");
- } else if (!child) {
- if (ptrace(PTRACE_TRACEME, 0, NULL, NULL))
- ksft_exit_fail_msg("PTRACE_TRACEME failed\n");
- ptracee_touch_xstate();
- raise(SIGTRAP);
- _exit(0);
- }
- do {
- wait(&status);
- } while (WSTOPSIG(status) != SIGTRAP);
- ptracer_inject_xstate(child);
- ptrace(PTRACE_DETACH, child, NULL, NULL);
- wait(&status);
- if (!WIFEXITED(status) || WEXITSTATUS(status))
- ksft_exit_fail_msg("ptracee exit error\n");
- }
- /*
- * Test signal delivery for the ABI compatibility.
- * See the ABI format: arch/x86/include/uapi/asm/sigcontext.h
- */
- /*
- * Avoid using printf() in signal handlers as it is not
- * async-signal-safe.
- */
- #define SIGNAL_BUF_LEN 1000
- static char signal_message_buffer[SIGNAL_BUF_LEN];
- static void sig_print(char *msg)
- {
- int left = SIGNAL_BUF_LEN - strlen(signal_message_buffer) - 1;
- strncat(signal_message_buffer, msg, left);
- }
- static struct xsave_buffer *stashed_xbuf;
- static void validate_sigfpstate(int sig, siginfo_t *si, void *ctx_void)
- {
- ucontext_t *ctx = (ucontext_t *)ctx_void;
- void *xbuf = ctx->uc_mcontext.fpregs;
- struct _fpx_sw_bytes *sw_bytes;
- uint32_t magic2;
- /* Reset the signal message buffer: */
- signal_message_buffer[0] = '\0';
- sw_bytes = get_fpx_sw_bytes(xbuf);
- if (sw_bytes->magic1 == FP_XSTATE_MAGIC1)
- sig_print("[OK]\t'magic1' is valid\n");
- else
- sig_print("[FAIL]\t'magic1' is not valid\n");
- if (get_fpx_sw_bytes_features(xbuf) & xstate.mask)
- sig_print("[OK]\t'xfeatures' in SW reserved area is valid\n");
- else
- sig_print("[FAIL]\t'xfeatures' in SW reserved area is not valid\n");
- if (get_xstatebv(xbuf) & xstate.mask)
- sig_print("[OK]\t'xfeatures' in XSAVE header is valid\n");
- else
- sig_print("[FAIL]\t'xfeatures' in XSAVE header is not valid\n");
- if (validate_xstate_same(stashed_xbuf, xbuf))
- sig_print("[OK]\txstate delivery was successful\n");
- else
- sig_print("[FAIL]\txstate delivery was not successful\n");
- magic2 = *(uint32_t *)(xbuf + sw_bytes->xstate_size);
- if (magic2 == FP_XSTATE_MAGIC2)
- sig_print("[OK]\t'magic2' is valid\n");
- else
- sig_print("[FAIL]\t'magic2' is not valid\n");
- set_rand_data(&xstate, xbuf);
- copy_xstate(stashed_xbuf, xbuf);
- }
- static void test_signal(void)
- {
- bool valid_xstate;
- /*
- * The signal handler will access this to verify xstate context
- * preservation.
- */
- stashed_xbuf = alloc_xbuf();
- if (!stashed_xbuf)
- ksft_exit_fail_msg("unable to allocate XSAVE buffer\n");
- printf("[RUN]\t%s: load xstate and raise SIGUSR1\n", xstate.name);
- sethandler(SIGUSR1, validate_sigfpstate, 0);
- load_rand_xstate(&xstate, stashed_xbuf);
- raise(SIGUSR1);
- /*
- * Immediately record the test result, deferring printf() to
- * prevent unintended state contamination by that.
- */
- valid_xstate = validate_xregs_same(stashed_xbuf);
- printf("%s", signal_message_buffer);
- printf("[RUN]\t%s: load new xstate from sighandler and check it after sigreturn\n",
- xstate.name);
- if (valid_xstate)
- printf("[OK]\txstate was restored correctly\n");
- else
- printf("[FAIL]\txstate restoration failed\n");
- clearhandler(SIGUSR1);
- free(stashed_xbuf);
- }
- void test_xstate(uint32_t feature_num)
- {
- const unsigned int ctxtsw_num_threads = 5, ctxtsw_iterations = 10;
- unsigned long features;
- long rc;
- if (!(XFEATURE_MASK_TEST_SUPPORTED & (1 << feature_num))) {
- ksft_print_msg("The xstate test does not fully support the component %u, yet.\n",
- feature_num);
- return;
- }
- rc = syscall(SYS_arch_prctl, ARCH_GET_XCOMP_SUPP, &features);
- if (rc || !(features & (1 << feature_num))) {
- ksft_print_msg("The kernel does not support feature number: %u\n", feature_num);
- return;
- }
- xstate = get_xstate_info(feature_num);
- if (!xstate.size || !xstate.xbuf_offset) {
- ksft_exit_fail_msg("invalid state size/offset (%d/%d)\n",
- xstate.size, xstate.xbuf_offset);
- }
- test_context_switch(ctxtsw_num_threads, ctxtsw_iterations);
- test_ptrace();
- test_signal();
- }
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