tools/testing/selftests/arm64/signal/test_signals_utils.h - linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 */
 /* Copyright (C) 2019 ARM Limited */

 #ifndef __TEST_SIGNALS_UTILS_H__
 #define __TEST_SIGNALS_UTILS_H__

 #include <assert.h>
 #include <stdio.h>
 #include <string.h>

 #include "test_signals.h"

 int test_init(struct tdescr *td);
 int test_setup(struct tdescr *td);
 void test_cleanup(struct tdescr *td);
 int test_run(struct tdescr *td);
 void test_result(struct tdescr *td);

 static inline bool feats_ok(struct tdescr *td)
 {
 	return (td->feats_required & td->feats_supported) == td->feats_required;
 }

 /*
  * Obtaining a valid and full-blown ucontext_t from userspace is tricky:
  * libc getcontext does() not save all the regs and messes with some of
  * them (pstate value in particular is not reliable).
  *
  * Here we use a service signal to grab the ucontext_t from inside a
  * dedicated signal handler, since there, it is populated by Kernel
  * itself in setup_sigframe(). The grabbed context is then stored and
  * made available in td->live_uc.
  *
  * As service-signal is used a SIGTRAP induced by a 'brk' instruction,
  * because here we have to avoid syscalls to trigger the signal since
  * they would cause any SVE sigframe content (if any) to be removed.
  *
  * Anyway this function really serves a dual purpose:
  *
  * 1. grab a valid sigcontext into td->live_uc for result analysis: in
  * such case it returns 1.
  *
  * 2. detect if, somehow, a previously grabbed live_uc context has been
  * used actively with a sigreturn: in such a case the execution would have
  * magically resumed in the middle of this function itself (seen_already==1):
  * in such a case return 0, since in fact we have not just simply grabbed
  * the context.
  *
  * This latter case is useful to detect when a fake_sigreturn test-case has
  * unexpectedly survived without hitting a SEGV.
  *
  * Note that the case of runtime dynamically sized sigframes (like in SVE
  * context) is still NOT addressed: sigframe size is supposed to be fixed
  * at sizeof(ucontext_t).
  */
 static __always_inline bool get_current_context(struct tdescr *td,
 						ucontext_t *dest_uc)
 {
 	static volatile bool seen_already;

 	assert(td && dest_uc);
 	/* it's a genuine invocation..reinit */
 	seen_already = 0;
 	td->live_uc_valid = 0;
 	td->live_sz = sizeof(*dest_uc);
 	memset(dest_uc, 0x00, td->live_sz);
 	td->live_uc = dest_uc;
 	/*
 	 * Grab ucontext_t triggering a SIGTRAP.
 	 *
 	 * Note that:
 	 * - live_uc_valid is declared volatile sig_atomic_t in
 	 *   struct tdescr since it will be changed inside the
 	 *   sig_copyctx handler
 	 * - the additional 'memory' clobber is there to avoid possible
 	 *   compiler's assumption on live_uc_valid and the content
 	 *   pointed by dest_uc, which are all changed inside the signal
 	 *   handler
 	 * - BRK causes a debug exception which is handled by the Kernel
 	 *   and finally causes the SIGTRAP signal to be delivered to this
 	 *   test thread. Since such delivery happens on the ret_to_user()
 	 *   /do_notify_resume() debug exception return-path, we are sure
 	 *   that the registered SIGTRAP handler has been run to completion
 	 *   before the execution path is restored here: as a consequence
 	 *   we can be sure that the volatile sig_atomic_t live_uc_valid
 	 *   carries a meaningful result. Being in a single thread context
 	 *   we'll also be sure that any access to memory modified by the
 	 *   handler (namely ucontext_t) will be visible once returned.
 	 * - note that since we are using a breakpoint instruction here
 	 *   to cause a SIGTRAP, the ucontext_t grabbed from the signal
 	 *   handler would naturally contain a PC pointing exactly to this
 	 *   BRK line, which means that, on return from the signal handler,
 	 *   or if we place the ucontext_t on the stack to fake a sigreturn,
 	 *   we'll end up in an infinite loop of BRK-SIGTRAP-handler.
 	 *   For this reason we take care to artificially move forward the
 	 *   PC to the next instruction while inside the signal handler.
 	 */
 	asm volatile ("brk #666"
 		      : "+m" (*dest_uc)
 		      :
 		      : "memory");

 	/*
 	 * If we get here with seen_already==1 it implies the td->live_uc
 	 * context has been used to get back here....this probably means
 	 * a test has failed to cause a SEGV...anyway live_uc does not
 	 * point to a just acquired copy of ucontext_t...so return 0
 	 */
 	if (seen_already) {
 		fprintf(stdout,
 			"Unexpected successful sigreturn detected: live_uc is stale !\n");
 		return 0;
 	}
 	seen_already = 1;

 	return td->live_uc_valid;
 }

 int fake_sigreturn(void *sigframe, size_t sz, int misalign_bytes);
 #endif
	/* SPDX-License-Identifier: GPL-2.0 */
	/* Copyright (C) 2019 ARM Limited */

	#ifndef __TEST_SIGNALS_UTILS_H__
	#define __TEST_SIGNALS_UTILS_H__

	#include <assert.h>
	#include <stdio.h>
	#include <string.h>

	#include "test_signals.h"

	int test_init(struct tdescr *td);
	int test_setup(struct tdescr *td);
	void test_cleanup(struct tdescr *td);
	int test_run(struct tdescr *td);
	void test_result(struct tdescr *td);

	static inline bool feats_ok(struct tdescr *td)
	{
	return (td->feats_required & td->feats_supported) == td->feats_required;
	}

	/*
	* Obtaining a valid and full-blown ucontext_t from userspace is tricky:
	* libc getcontext does() not save all the regs and messes with some of
	* them (pstate value in particular is not reliable).
	*
	* Here we use a service signal to grab the ucontext_t from inside a
	* dedicated signal handler, since there, it is populated by Kernel
	* itself in setup_sigframe(). The grabbed context is then stored and
	* made available in td->live_uc.
	*
	* As service-signal is used a SIGTRAP induced by a 'brk' instruction,
	* because here we have to avoid syscalls to trigger the signal since
	* they would cause any SVE sigframe content (if any) to be removed.
	*
	* Anyway this function really serves a dual purpose:
	*
	* 1. grab a valid sigcontext into td->live_uc for result analysis: in
	* such case it returns 1.
	*
	* 2. detect if, somehow, a previously grabbed live_uc context has been
	* used actively with a sigreturn: in such a case the execution would have
	* magically resumed in the middle of this function itself (seen_already==1):
	* in such a case return 0, since in fact we have not just simply grabbed
	* the context.
	*
	* This latter case is useful to detect when a fake_sigreturn test-case has
	* unexpectedly survived without hitting a SEGV.
	*
	* Note that the case of runtime dynamically sized sigframes (like in SVE
	* context) is still NOT addressed: sigframe size is supposed to be fixed
	* at sizeof(ucontext_t).
	*/
	static __always_inline bool get_current_context(struct tdescr *td,
	ucontext_t *dest_uc)
	{
	static volatile bool seen_already;

	assert(td && dest_uc);
	/* it's a genuine invocation..reinit */
	seen_already = 0;
	td->live_uc_valid = 0;
	td->live_sz = sizeof(*dest_uc);
	memset(dest_uc, 0x00, td->live_sz);
	td->live_uc = dest_uc;
	/*
	* Grab ucontext_t triggering a SIGTRAP.
	*
	* Note that:
	* - live_uc_valid is declared volatile sig_atomic_t in
	* struct tdescr since it will be changed inside the
	* sig_copyctx handler
	* - the additional 'memory' clobber is there to avoid possible
	* compiler's assumption on live_uc_valid and the content
	* pointed by dest_uc, which are all changed inside the signal
	* handler
	* - BRK causes a debug exception which is handled by the Kernel
	* and finally causes the SIGTRAP signal to be delivered to this
	* test thread. Since such delivery happens on the ret_to_user()
	* /do_notify_resume() debug exception return-path, we are sure
	* that the registered SIGTRAP handler has been run to completion
	* before the execution path is restored here: as a consequence
	* we can be sure that the volatile sig_atomic_t live_uc_valid
	* carries a meaningful result. Being in a single thread context
	* we'll also be sure that any access to memory modified by the
	* handler (namely ucontext_t) will be visible once returned.
	* - note that since we are using a breakpoint instruction here
	* to cause a SIGTRAP, the ucontext_t grabbed from the signal
	* handler would naturally contain a PC pointing exactly to this
	* BRK line, which means that, on return from the signal handler,
	* or if we place the ucontext_t on the stack to fake a sigreturn,
	* we'll end up in an infinite loop of BRK-SIGTRAP-handler.
	* For this reason we take care to artificially move forward the
	* PC to the next instruction while inside the signal handler.
	*/
	asm volatile ("brk #666"
	: "+m" (*dest_uc)
	:
	: "memory");

	/*
	* If we get here with seen_already==1 it implies the td->live_uc
	* context has been used to get back here....this probably means
	* a test has failed to cause a SEGV...anyway live_uc does not
	* point to a just acquired copy of ucontext_t...so return 0
	*/
	if (seen_already) {
	fprintf(stdout,
	"Unexpected successful sigreturn detected: live_uc is stale !\n");
	return 0;
	}
	seen_already = 1;

	return td->live_uc_valid;
	}

	int fake_sigreturn(void *sigframe, size_t sz, int misalign_bytes);
	#endif