tools/testing/selftests/powerpc/tm/tm-signal-pagefault.c - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 /*
  * Copyright 2020, Gustavo Luiz Duarte, IBM Corp.
  *
  * This test starts a transaction and triggers a signal, forcing a pagefault to
  * happen when the kernel signal handling code touches the user signal stack.
  *
  * In order to avoid pre-faulting the signal stack memory and to force the
  * pagefault to happen precisely in the kernel signal handling code, the
  * pagefault handling is done in userspace using the userfaultfd facility.
  *
  * Further pagefaults are triggered by crafting the signal handler's ucontext
  * to point to additional memory regions managed by the userfaultfd, so using
  * the same mechanism used to avoid pre-faulting the signal stack memory.
  *
  * On failure (bug is present) kernel crashes or never returns control back to
  * userspace. If bug is not present, tests completes almost immediately.
  */

 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
 #include <linux/userfaultfd.h>
 #include <poll.h>
 #include <unistd.h>
 #include <sys/ioctl.h>
 #include <sys/syscall.h>
 #include <fcntl.h>
 #include <sys/mman.h>
 #include <pthread.h>
 #include <signal.h>
 #include <errno.h>

 #include "tm.h"


 #define UF_MEM_SIZE 655360	/* 10 x 64k pages */

 /* Memory handled by userfaultfd */
 static char *uf_mem;
 static size_t uf_mem_offset = 0;

 /*
  * Data that will be copied into the faulting pages (instead of zero-filled
  * pages). This is used to make the test more reliable and avoid segfaulting
  * when we return from the signal handler. Since we are making the signal
  * handler's ucontext point to newly allocated memory, when that memory is
  * paged-in it will contain the expected content.
  */
 static char backing_mem[UF_MEM_SIZE];

 static size_t pagesize;

 /*
  * Return a chunk of at least 'size' bytes of memory that will be handled by
  * userfaultfd. If 'backing_data' is not NULL, its content will be save to
  * 'backing_mem' and then copied into the faulting pages when the page fault
  * is handled.
  */
 void *get_uf_mem(size_t size, void *backing_data)
 {
 	void *ret;

 	if (uf_mem_offset + size > UF_MEM_SIZE) {
 		fprintf(stderr, "Requesting more uf_mem than expected!\n");
 		exit(EXIT_FAILURE);
 	}

 	ret = &uf_mem[uf_mem_offset];

 	/* Save the data that will be copied into the faulting page */
 	if (backing_data != NULL)
 		memcpy(&backing_mem[uf_mem_offset], backing_data, size);

 	/* Reserve the requested amount of uf_mem */
 	uf_mem_offset += size;
 	/* Keep uf_mem_offset aligned to the page size (round up) */
 	uf_mem_offset = (uf_mem_offset + pagesize - 1) & ~(pagesize - 1);

 	return ret;
 }

 void *fault_handler_thread(void *arg)
 {
 	struct uffd_msg msg;	/* Data read from userfaultfd */
 	long uffd;		/* userfaultfd file descriptor */
 	struct uffdio_copy uffdio_copy;
 	struct pollfd pollfd;
 	ssize_t nread, offset;

 	uffd = (long) arg;

 	for (;;) {
 		pollfd.fd = uffd;
 		pollfd.events = POLLIN;
 		if (poll(&pollfd, 1, -1) == -1) {
 			perror("poll() failed");
 			exit(EXIT_FAILURE);
 		}

 		nread = read(uffd, &msg, sizeof(msg));
 		if (nread == 0) {
 			fprintf(stderr, "read(): EOF on userfaultfd\n");
 			exit(EXIT_FAILURE);
 		}

 		if (nread == -1) {
 			perror("read() failed");
 			exit(EXIT_FAILURE);
 		}

 		/* We expect only one kind of event */
 		if (msg.event != UFFD_EVENT_PAGEFAULT) {
 			fprintf(stderr, "Unexpected event on userfaultfd\n");
 			exit(EXIT_FAILURE);
 		}

 		/*
 		 * We need to handle page faults in units of pages(!).
 		 * So, round faulting address down to page boundary.
 		 */
 		uffdio_copy.dst = msg.arg.pagefault.address & ~(pagesize-1);

 		offset = (char *) uffdio_copy.dst - uf_mem;
 		uffdio_copy.src = (unsigned long) &backing_mem[offset];

 		uffdio_copy.len = pagesize;
 		uffdio_copy.mode = 0;
 		uffdio_copy.copy = 0;
 		if (ioctl(uffd, UFFDIO_COPY, &uffdio_copy) == -1) {
 			perror("ioctl-UFFDIO_COPY failed");
 			exit(EXIT_FAILURE);
 		}
 	}
 }

 void setup_uf_mem(void)
 {
 	long uffd;		/* userfaultfd file descriptor */
 	pthread_t thr;
 	struct uffdio_api uffdio_api;
 	struct uffdio_register uffdio_register;
 	int ret;

 	pagesize = sysconf(_SC_PAGE_SIZE);

 	/* Create and enable userfaultfd object */
 	uffd = syscall(__NR_userfaultfd, O_CLOEXEC | O_NONBLOCK);
 	if (uffd == -1) {
 		perror("userfaultfd() failed");
 		exit(EXIT_FAILURE);
 	}
 	uffdio_api.api = UFFD_API;
 	uffdio_api.features = 0;
 	if (ioctl(uffd, UFFDIO_API, &uffdio_api) == -1) {
 		perror("ioctl-UFFDIO_API failed");
 		exit(EXIT_FAILURE);
 	}

 	/*
 	 * Create a private anonymous mapping. The memory will be demand-zero
 	 * paged, that is, not yet allocated. When we actually touch the memory
 	 * the related page will be allocated via the userfaultfd mechanism.
 	 */
 	uf_mem = mmap(NULL, UF_MEM_SIZE, PROT_READ | PROT_WRITE,
 		      MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
 	if (uf_mem == MAP_FAILED) {
 		perror("mmap() failed");
 		exit(EXIT_FAILURE);
 	}

 	/*
 	 * Register the memory range of the mapping we've just mapped to be
 	 * handled by the userfaultfd object. In 'mode' we request to track
 	 * missing pages (i.e. pages that have not yet been faulted-in).
 	 */
 	uffdio_register.range.start = (unsigned long) uf_mem;
 	uffdio_register.range.len = UF_MEM_SIZE;
 	uffdio_register.mode = UFFDIO_REGISTER_MODE_MISSING;
 	if (ioctl(uffd, UFFDIO_REGISTER, &uffdio_register) == -1) {
 		perror("ioctl-UFFDIO_REGISTER");
 		exit(EXIT_FAILURE);
 	}

 	/* Create a thread that will process the userfaultfd events */
 	ret = pthread_create(&thr, NULL, fault_handler_thread, (void *) uffd);
 	if (ret != 0) {
 		fprintf(stderr, "pthread_create(): Error. Returned %d\n", ret);
 		exit(EXIT_FAILURE);
 	}
 }

 /*
  * Assumption: the signal was delivered while userspace was in transactional or
  * suspended state, i.e. uc->uc_link != NULL.
  */
 void signal_handler(int signo, siginfo_t *si, void *uc)
 {
 	ucontext_t *ucp = uc;

 	/* Skip 'trap' after returning, otherwise we get a SIGTRAP again */
 	ucp->uc_link->uc_mcontext.regs->nip += 4;

 	ucp->uc_mcontext.v_regs =
 		get_uf_mem(sizeof(elf_vrreg_t), ucp->uc_mcontext.v_regs);

 	ucp->uc_link->uc_mcontext.v_regs =
 		get_uf_mem(sizeof(elf_vrreg_t), ucp->uc_link->uc_mcontext.v_regs);

 	ucp->uc_link = get_uf_mem(sizeof(ucontext_t), ucp->uc_link);
 }

 bool have_userfaultfd(void)
 {
 	long rc;

 	errno = 0;
 	rc = syscall(__NR_userfaultfd, -1);

 	return rc == 0 || errno != ENOSYS;
 }

 int tm_signal_pagefault(void)
 {
 	struct sigaction sa;
 	stack_t ss;

 	SKIP_IF(!have_htm());
 	SKIP_IF(htm_is_synthetic());
 	SKIP_IF(!have_userfaultfd());

 	setup_uf_mem();

 	/*
 	 * Set an alternative stack that will generate a page fault when the
 	 * signal is raised. The page fault will be treated via userfaultfd,
 	 * i.e. via fault_handler_thread.
 	 */
 	ss.ss_sp = get_uf_mem(SIGSTKSZ, NULL);
 	ss.ss_size = SIGSTKSZ;
 	ss.ss_flags = 0;
 	if (sigaltstack(&ss, NULL) == -1) {
 		perror("sigaltstack() failed");
 		exit(EXIT_FAILURE);
 	}

 	sa.sa_flags = SA_SIGINFO | SA_ONSTACK;
 	sa.sa_sigaction = signal_handler;
 	if (sigaction(SIGTRAP, &sa, NULL) == -1) {
 		perror("sigaction() failed");
 		exit(EXIT_FAILURE);
 	}

 	/* Trigger a SIGTRAP in transactional state */
 	asm __volatile__(
 			"tbegin.;"
 			"beq    1f;"
 			"trap;"
 			"1: ;"
 			: : : "memory");

 	/* Trigger a SIGTRAP in suspended state */
 	asm __volatile__(
 			"tbegin.;"
 			"beq    1f;"
 			"tsuspend.;"
 			"trap;"
 			"tresume.;"
 			"1: ;"
 			: : : "memory");

 	return EXIT_SUCCESS;
 }

 int main(int argc, char **argv)
 {
 	/*
 	 * Depending on kernel config, the TM Bad Thing might not result in a
 	 * crash, instead the kernel never returns control back to userspace, so
 	 * set a tight timeout. If the test passes it completes almost
 	 * immediately.
 	 */
 	test_harness_set_timeout(2);
 	return test_harness(tm_signal_pagefault, "tm_signal_pagefault");
 }
	// SPDX-License-Identifier: GPL-2.0
	/*
	* Copyright 2020, Gustavo Luiz Duarte, IBM Corp.
	*
	* This test starts a transaction and triggers a signal, forcing a pagefault to
	* happen when the kernel signal handling code touches the user signal stack.
	*
	* In order to avoid pre-faulting the signal stack memory and to force the
	* pagefault to happen precisely in the kernel signal handling code, the
	* pagefault handling is done in userspace using the userfaultfd facility.
	*
	* Further pagefaults are triggered by crafting the signal handler's ucontext
	* to point to additional memory regions managed by the userfaultfd, so using
	* the same mechanism used to avoid pre-faulting the signal stack memory.
	*
	* On failure (bug is present) kernel crashes or never returns control back to
	* userspace. If bug is not present, tests completes almost immediately.
	*/

	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>
	#include <linux/userfaultfd.h>
	#include <poll.h>
	#include <unistd.h>
	#include <sys/ioctl.h>
	#include <sys/syscall.h>
	#include <fcntl.h>
	#include <sys/mman.h>
	#include <pthread.h>
	#include <signal.h>
	#include <errno.h>

	#include "tm.h"


	#define UF_MEM_SIZE 655360 /* 10 x 64k pages */

	/* Memory handled by userfaultfd */
	static char *uf_mem;
	static size_t uf_mem_offset = 0;

	/*
	* Data that will be copied into the faulting pages (instead of zero-filled
	* pages). This is used to make the test more reliable and avoid segfaulting
	* when we return from the signal handler. Since we are making the signal
	* handler's ucontext point to newly allocated memory, when that memory is
	* paged-in it will contain the expected content.
	*/
	static char backing_mem[UF_MEM_SIZE];

	static size_t pagesize;

	/*
	* Return a chunk of at least 'size' bytes of memory that will be handled by
	* userfaultfd. If 'backing_data' is not NULL, its content will be save to
	* 'backing_mem' and then copied into the faulting pages when the page fault
	* is handled.
	*/
	void get_uf_mem(size_t size, void backing_data)
	{
	void *ret;

	if (uf_mem_offset + size > UF_MEM_SIZE) {
	fprintf(stderr, "Requesting more uf_mem than expected!\n");
	exit(EXIT_FAILURE);
	}

	ret = &uf_mem[uf_mem_offset];

	/* Save the data that will be copied into the faulting page */
	if (backing_data != NULL)
	memcpy(&backing_mem[uf_mem_offset], backing_data, size);

	/* Reserve the requested amount of uf_mem */
	uf_mem_offset += size;
	/* Keep uf_mem_offset aligned to the page size (round up) */
	uf_mem_offset = (uf_mem_offset + pagesize - 1) & ~(pagesize - 1);

	return ret;
	}

	void fault_handler_thread(void arg)
	{
	struct uffd_msg msg; /* Data read from userfaultfd */
	long uffd; /* userfaultfd file descriptor */
	struct uffdio_copy uffdio_copy;
	struct pollfd pollfd;
	ssize_t nread, offset;

	uffd = (long) arg;

	for (;;) {
	pollfd.fd = uffd;
	pollfd.events = POLLIN;
	if (poll(&pollfd, 1, -1) == -1) {
	perror("poll() failed");
	exit(EXIT_FAILURE);
	}

	nread = read(uffd, &msg, sizeof(msg));
	if (nread == 0) {
	fprintf(stderr, "read(): EOF on userfaultfd\n");
	exit(EXIT_FAILURE);
	}

	if (nread == -1) {
	perror("read() failed");
	exit(EXIT_FAILURE);
	}

	/* We expect only one kind of event */
	if (msg.event != UFFD_EVENT_PAGEFAULT) {
	fprintf(stderr, "Unexpected event on userfaultfd\n");
	exit(EXIT_FAILURE);
	}

	/*
	* We need to handle page faults in units of pages(!).
	* So, round faulting address down to page boundary.
	*/
	uffdio_copy.dst = msg.arg.pagefault.address & ~(pagesize-1);

	offset = (char *) uffdio_copy.dst - uf_mem;
	uffdio_copy.src = (unsigned long) &backing_mem[offset];

	uffdio_copy.len = pagesize;
	uffdio_copy.mode = 0;
	uffdio_copy.copy = 0;
	if (ioctl(uffd, UFFDIO_COPY, &uffdio_copy) == -1) {
	perror("ioctl-UFFDIO_COPY failed");
	exit(EXIT_FAILURE);
	}
	}
	}

	void setup_uf_mem(void)
	{
	long uffd; /* userfaultfd file descriptor */
	pthread_t thr;
	struct uffdio_api uffdio_api;
	struct uffdio_register uffdio_register;
	int ret;

	pagesize = sysconf(_SC_PAGE_SIZE);

	/* Create and enable userfaultfd object */
	uffd = syscall(__NR_userfaultfd, O_CLOEXEC \| O_NONBLOCK);
	if (uffd == -1) {
	perror("userfaultfd() failed");
	exit(EXIT_FAILURE);
	}
	uffdio_api.api = UFFD_API;
	uffdio_api.features = 0;
	if (ioctl(uffd, UFFDIO_API, &uffdio_api) == -1) {
	perror("ioctl-UFFDIO_API failed");
	exit(EXIT_FAILURE);
	}

	/*
	* Create a private anonymous mapping. The memory will be demand-zero
	* paged, that is, not yet allocated. When we actually touch the memory
	* the related page will be allocated via the userfaultfd mechanism.
	*/
	uf_mem = mmap(NULL, UF_MEM_SIZE, PROT_READ \| PROT_WRITE,
	MAP_PRIVATE \| MAP_ANONYMOUS, -1, 0);
	if (uf_mem == MAP_FAILED) {
	perror("mmap() failed");
	exit(EXIT_FAILURE);
	}

	/*
	* Register the memory range of the mapping we've just mapped to be
	* handled by the userfaultfd object. In 'mode' we request to track
	* missing pages (i.e. pages that have not yet been faulted-in).
	*/
	uffdio_register.range.start = (unsigned long) uf_mem;
	uffdio_register.range.len = UF_MEM_SIZE;
	uffdio_register.mode = UFFDIO_REGISTER_MODE_MISSING;
	if (ioctl(uffd, UFFDIO_REGISTER, &uffdio_register) == -1) {
	perror("ioctl-UFFDIO_REGISTER");
	exit(EXIT_FAILURE);
	}

	/* Create a thread that will process the userfaultfd events */
	ret = pthread_create(&thr, NULL, fault_handler_thread, (void *) uffd);
	if (ret != 0) {
	fprintf(stderr, "pthread_create(): Error. Returned %d\n", ret);
	exit(EXIT_FAILURE);
	}
	}

	/*
	* Assumption: the signal was delivered while userspace was in transactional or
	* suspended state, i.e. uc->uc_link != NULL.
	*/
	void signal_handler(int signo, siginfo_t si, void uc)
	{
	ucontext_t *ucp = uc;

	/* Skip 'trap' after returning, otherwise we get a SIGTRAP again */
	ucp->uc_link->uc_mcontext.regs->nip += 4;

	ucp->uc_mcontext.v_regs =
	get_uf_mem(sizeof(elf_vrreg_t), ucp->uc_mcontext.v_regs);

	ucp->uc_link->uc_mcontext.v_regs =
	get_uf_mem(sizeof(elf_vrreg_t), ucp->uc_link->uc_mcontext.v_regs);

	ucp->uc_link = get_uf_mem(sizeof(ucontext_t), ucp->uc_link);
	}

	bool have_userfaultfd(void)
	{
	long rc;

	errno = 0;
	rc = syscall(__NR_userfaultfd, -1);

	return rc == 0 \|\| errno != ENOSYS;
	}

	int tm_signal_pagefault(void)
	{
	struct sigaction sa;
	stack_t ss;

	SKIP_IF(!have_htm());
	SKIP_IF(htm_is_synthetic());
	SKIP_IF(!have_userfaultfd());

	setup_uf_mem();

	/*
	* Set an alternative stack that will generate a page fault when the
	* signal is raised. The page fault will be treated via userfaultfd,
	* i.e. via fault_handler_thread.
	*/
	ss.ss_sp = get_uf_mem(SIGSTKSZ, NULL);
	ss.ss_size = SIGSTKSZ;
	ss.ss_flags = 0;
	if (sigaltstack(&ss, NULL) == -1) {
	perror("sigaltstack() failed");
	exit(EXIT_FAILURE);
	}

	sa.sa_flags = SA_SIGINFO \| SA_ONSTACK;
	sa.sa_sigaction = signal_handler;
	if (sigaction(SIGTRAP, &sa, NULL) == -1) {
	perror("sigaction() failed");
	exit(EXIT_FAILURE);
	}

	/* Trigger a SIGTRAP in transactional state */
	asm __volatile__(
	"tbegin.;"
	"beq 1f;"
	"trap;"
	"1: ;"
	: : : "memory");

	/* Trigger a SIGTRAP in suspended state */
	asm __volatile__(
	"tbegin.;"
	"beq 1f;"
	"tsuspend.;"
	"trap;"
	"tresume.;"
	"1: ;"
	: : : "memory");

	return EXIT_SUCCESS;
	}

	int main(int argc, char **argv)
	{
	/*
	* Depending on kernel config, the TM Bad Thing might not result in a
	* crash, instead the kernel never returns control back to userspace, so
	* set a tight timeout. If the test passes it completes almost
	* immediately.
	*/
	test_harness_set_timeout(2);
	return test_harness(tm_signal_pagefault, "tm_signal_pagefault");
	}