| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Suren Baghdasaryan | 3522 | 99.83% | 4 | 80.00% |
| Unknown | 6 | 0.17% | 1 | 20.00% |
| Total | 3528 | 5 |
// SPDX-License-Identifier: GPL-2.0-only /* * Copyright 2022 Google LLC. * Author: Suren Baghdasaryan <surenb@google.com> * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ /* * Fork a child that concurrently modifies address space while the main * process is reading /proc/$PID/maps and verifying the results. Address * space modifications include: * VMA splitting and merging * */ #define _GNU_SOURCE #include "../kselftest_harness.h" #include <errno.h> #include <fcntl.h> #include <pthread.h> #include <stdbool.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <unistd.h> #include <sys/mman.h> #include <sys/stat.h> #include <sys/types.h> #include <sys/wait.h> /* /proc/pid/maps parsing routines */ struct page_content { char *data; ssize_t size; }; #define LINE_MAX_SIZE 256 struct line_content { char text[LINE_MAX_SIZE]; unsigned long start_addr; unsigned long end_addr; }; enum test_state { INIT, CHILD_READY, PARENT_READY, SETUP_READY, SETUP_MODIFY_MAPS, SETUP_MAPS_MODIFIED, SETUP_RESTORE_MAPS, SETUP_MAPS_RESTORED, TEST_READY, TEST_DONE, }; struct vma_modifier_info; FIXTURE(proc_maps_race) { struct vma_modifier_info *mod_info; struct page_content page1; struct page_content page2; struct line_content last_line; struct line_content first_line; unsigned long duration_sec; int shared_mem_size; int page_size; int vma_count; bool verbose; int maps_fd; pid_t pid; }; typedef bool (*vma_modifier_op)(FIXTURE_DATA(proc_maps_race) *self); typedef bool (*vma_mod_result_check_op)(struct line_content *mod_last_line, struct line_content *mod_first_line, struct line_content *restored_last_line, struct line_content *restored_first_line); struct vma_modifier_info { int vma_count; void *addr; int prot; void *next_addr; vma_modifier_op vma_modify; vma_modifier_op vma_restore; vma_mod_result_check_op vma_mod_check; pthread_mutex_t sync_lock; pthread_cond_t sync_cond; enum test_state curr_state; bool exit; void *child_mapped_addr[]; }; static bool read_two_pages(FIXTURE_DATA(proc_maps_race) *self) { ssize_t bytes_read; if (lseek(self->maps_fd, 0, SEEK_SET) < 0) return false; bytes_read = read(self->maps_fd, self->page1.data, self->page_size); if (bytes_read <= 0) return false; self->page1.size = bytes_read; bytes_read = read(self->maps_fd, self->page2.data, self->page_size); if (bytes_read <= 0) return false; self->page2.size = bytes_read; return true; } static void copy_first_line(struct page_content *page, char *first_line) { char *pos = strchr(page->data, '\n'); strncpy(first_line, page->data, pos - page->data); first_line[pos - page->data] = '\0'; } static void copy_last_line(struct page_content *page, char *last_line) { /* Get the last line in the first page */ const char *end = page->data + page->size - 1; /* skip last newline */ const char *pos = end - 1; /* search previous newline */ while (pos[-1] != '\n') pos--; strncpy(last_line, pos, end - pos); last_line[end - pos] = '\0'; } /* Read the last line of the first page and the first line of the second page */ static bool read_boundary_lines(FIXTURE_DATA(proc_maps_race) *self, struct line_content *last_line, struct line_content *first_line) { if (!read_two_pages(self)) return false; copy_last_line(&self->page1, last_line->text); copy_first_line(&self->page2, first_line->text); return sscanf(last_line->text, "%lx-%lx", &last_line->start_addr, &last_line->end_addr) == 2 && sscanf(first_line->text, "%lx-%lx", &first_line->start_addr, &first_line->end_addr) == 2; } /* Thread synchronization routines */ static void wait_for_state(struct vma_modifier_info *mod_info, enum test_state state) { pthread_mutex_lock(&mod_info->sync_lock); while (mod_info->curr_state != state) pthread_cond_wait(&mod_info->sync_cond, &mod_info->sync_lock); pthread_mutex_unlock(&mod_info->sync_lock); } static void signal_state(struct vma_modifier_info *mod_info, enum test_state state) { pthread_mutex_lock(&mod_info->sync_lock); mod_info->curr_state = state; pthread_cond_signal(&mod_info->sync_cond); pthread_mutex_unlock(&mod_info->sync_lock); } static void stop_vma_modifier(struct vma_modifier_info *mod_info) { wait_for_state(mod_info, SETUP_READY); mod_info->exit = true; signal_state(mod_info, SETUP_MODIFY_MAPS); } static void print_first_lines(char *text, int nr) { const char *end = text; while (nr && (end = strchr(end, '\n')) != NULL) { nr--; end++; } if (end) { int offs = end - text; text[offs] = '\0'; printf("%s", text); text[offs] = '\n'; printf("\n"); } else { printf("%s", text); } } static void print_last_lines(char *text, int nr) { const char *start = text + strlen(text); nr++; /* to ignore the last newline */ while (nr) { while (start > text && *start != '\n') start--; nr--; start--; } printf("%s", start); } static void print_boundaries(const char *title, FIXTURE_DATA(proc_maps_race) *self) { if (!self->verbose) return; printf("%s", title); /* Print 3 boundary lines from each page */ print_last_lines(self->page1.data, 3); printf("-----------------page boundary-----------------\n"); print_first_lines(self->page2.data, 3); } static bool print_boundaries_on(bool condition, const char *title, FIXTURE_DATA(proc_maps_race) *self) { if (self->verbose && condition) print_boundaries(title, self); return condition; } static void report_test_start(const char *name, bool verbose) { if (verbose) printf("==== %s ====\n", name); } static struct timespec print_ts; static void start_test_loop(struct timespec *ts, bool verbose) { if (verbose) print_ts.tv_sec = ts->tv_sec; } static void end_test_iteration(struct timespec *ts, bool verbose) { if (!verbose) return; /* Update every second */ if (print_ts.tv_sec == ts->tv_sec) return; printf("."); fflush(stdout); print_ts.tv_sec = ts->tv_sec; } static void end_test_loop(bool verbose) { if (verbose) printf("\n"); } static bool capture_mod_pattern(FIXTURE_DATA(proc_maps_race) *self, struct line_content *mod_last_line, struct line_content *mod_first_line, struct line_content *restored_last_line, struct line_content *restored_first_line) { print_boundaries("Before modification", self); signal_state(self->mod_info, SETUP_MODIFY_MAPS); wait_for_state(self->mod_info, SETUP_MAPS_MODIFIED); /* Copy last line of the first page and first line of the last page */ if (!read_boundary_lines(self, mod_last_line, mod_first_line)) return false; print_boundaries("After modification", self); signal_state(self->mod_info, SETUP_RESTORE_MAPS); wait_for_state(self->mod_info, SETUP_MAPS_RESTORED); /* Copy last line of the first page and first line of the last page */ if (!read_boundary_lines(self, restored_last_line, restored_first_line)) return false; print_boundaries("After restore", self); if (!self->mod_info->vma_mod_check(mod_last_line, mod_first_line, restored_last_line, restored_first_line)) return false; /* * The content of these lines after modify+resore should be the same * as the original. */ return strcmp(restored_last_line->text, self->last_line.text) == 0 && strcmp(restored_first_line->text, self->first_line.text) == 0; } static inline bool split_vma(FIXTURE_DATA(proc_maps_race) *self) { return mmap(self->mod_info->addr, self->page_size, self->mod_info->prot | PROT_EXEC, MAP_PRIVATE | MAP_ANONYMOUS | MAP_FIXED, -1, 0) != MAP_FAILED; } static inline bool merge_vma(FIXTURE_DATA(proc_maps_race) *self) { return mmap(self->mod_info->addr, self->page_size, self->mod_info->prot, MAP_PRIVATE | MAP_ANONYMOUS | MAP_FIXED, -1, 0) != MAP_FAILED; } static inline bool check_split_result(struct line_content *mod_last_line, struct line_content *mod_first_line, struct line_content *restored_last_line, struct line_content *restored_first_line) { /* Make sure vmas at the boundaries are changing */ return strcmp(mod_last_line->text, restored_last_line->text) != 0 && strcmp(mod_first_line->text, restored_first_line->text) != 0; } static inline bool shrink_vma(FIXTURE_DATA(proc_maps_race) *self) { return mremap(self->mod_info->addr, self->page_size * 3, self->page_size, 0) != MAP_FAILED; } static inline bool expand_vma(FIXTURE_DATA(proc_maps_race) *self) { return mremap(self->mod_info->addr, self->page_size, self->page_size * 3, 0) != MAP_FAILED; } static inline bool check_shrink_result(struct line_content *mod_last_line, struct line_content *mod_first_line, struct line_content *restored_last_line, struct line_content *restored_first_line) { /* Make sure only the last vma of the first page is changing */ return strcmp(mod_last_line->text, restored_last_line->text) != 0 && strcmp(mod_first_line->text, restored_first_line->text) == 0; } static inline bool remap_vma(FIXTURE_DATA(proc_maps_race) *self) { /* * Remap the last page of the next vma into the middle of the vma. * This splits the current vma and the first and middle parts (the * parts at lower addresses) become the last vma objserved in the * first page and the first vma observed in the last page. */ return mremap(self->mod_info->next_addr + self->page_size * 2, self->page_size, self->page_size, MREMAP_FIXED | MREMAP_MAYMOVE | MREMAP_DONTUNMAP, self->mod_info->addr + self->page_size) != MAP_FAILED; } static inline bool patch_vma(FIXTURE_DATA(proc_maps_race) *self) { return mprotect(self->mod_info->addr + self->page_size, self->page_size, self->mod_info->prot) == 0; } static inline bool check_remap_result(struct line_content *mod_last_line, struct line_content *mod_first_line, struct line_content *restored_last_line, struct line_content *restored_first_line) { /* Make sure vmas at the boundaries are changing */ return strcmp(mod_last_line->text, restored_last_line->text) != 0 && strcmp(mod_first_line->text, restored_first_line->text) != 0; } FIXTURE_SETUP(proc_maps_race) { const char *verbose = getenv("VERBOSE"); const char *duration = getenv("DURATION"); struct vma_modifier_info *mod_info; pthread_mutexattr_t mutex_attr; pthread_condattr_t cond_attr; unsigned long duration_sec; char fname[32]; self->page_size = (unsigned long)sysconf(_SC_PAGESIZE); self->verbose = verbose && !strncmp(verbose, "1", 1); duration_sec = duration ? atol(duration) : 0; self->duration_sec = duration_sec ? duration_sec : 5UL; /* * Have to map enough vmas for /proc/pid/maps to contain more than one * page worth of vmas. Assume at least 32 bytes per line in maps output */ self->vma_count = self->page_size / 32 + 1; self->shared_mem_size = sizeof(struct vma_modifier_info) + self->vma_count * sizeof(void *); /* map shared memory for communication with the child process */ self->mod_info = (struct vma_modifier_info *)mmap(NULL, self->shared_mem_size, PROT_READ | PROT_WRITE, MAP_SHARED | MAP_ANONYMOUS, -1, 0); ASSERT_NE(self->mod_info, MAP_FAILED); mod_info = self->mod_info; /* Initialize shared members */ pthread_mutexattr_init(&mutex_attr); pthread_mutexattr_setpshared(&mutex_attr, PTHREAD_PROCESS_SHARED); ASSERT_EQ(pthread_mutex_init(&mod_info->sync_lock, &mutex_attr), 0); pthread_condattr_init(&cond_attr); pthread_condattr_setpshared(&cond_attr, PTHREAD_PROCESS_SHARED); ASSERT_EQ(pthread_cond_init(&mod_info->sync_cond, &cond_attr), 0); mod_info->vma_count = self->vma_count; mod_info->curr_state = INIT; mod_info->exit = false; self->pid = fork(); if (!self->pid) { /* Child process modifying the address space */ int prot = PROT_READ | PROT_WRITE; int i; for (i = 0; i < mod_info->vma_count; i++) { mod_info->child_mapped_addr[i] = mmap(NULL, self->page_size * 3, prot, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0); ASSERT_NE(mod_info->child_mapped_addr[i], MAP_FAILED); /* change protection in adjacent maps to prevent merging */ prot ^= PROT_WRITE; } signal_state(mod_info, CHILD_READY); wait_for_state(mod_info, PARENT_READY); while (true) { signal_state(mod_info, SETUP_READY); wait_for_state(mod_info, SETUP_MODIFY_MAPS); if (mod_info->exit) break; ASSERT_TRUE(mod_info->vma_modify(self)); signal_state(mod_info, SETUP_MAPS_MODIFIED); wait_for_state(mod_info, SETUP_RESTORE_MAPS); ASSERT_TRUE(mod_info->vma_restore(self)); signal_state(mod_info, SETUP_MAPS_RESTORED); wait_for_state(mod_info, TEST_READY); while (mod_info->curr_state != TEST_DONE) { ASSERT_TRUE(mod_info->vma_modify(self)); ASSERT_TRUE(mod_info->vma_restore(self)); } } for (i = 0; i < mod_info->vma_count; i++) munmap(mod_info->child_mapped_addr[i], self->page_size * 3); exit(0); } sprintf(fname, "/proc/%d/maps", self->pid); self->maps_fd = open(fname, O_RDONLY); ASSERT_NE(self->maps_fd, -1); /* Wait for the child to map the VMAs */ wait_for_state(mod_info, CHILD_READY); /* Read first two pages */ self->page1.data = malloc(self->page_size); ASSERT_NE(self->page1.data, NULL); self->page2.data = malloc(self->page_size); ASSERT_NE(self->page2.data, NULL); ASSERT_TRUE(read_boundary_lines(self, &self->last_line, &self->first_line)); /* * Find the addresses corresponding to the last line in the first page * and the first line in the last page. */ mod_info->addr = NULL; mod_info->next_addr = NULL; for (int i = 0; i < mod_info->vma_count; i++) { if (mod_info->child_mapped_addr[i] == (void *)self->last_line.start_addr) { mod_info->addr = mod_info->child_mapped_addr[i]; mod_info->prot = PROT_READ; /* Even VMAs have write permission */ if ((i % 2) == 0) mod_info->prot |= PROT_WRITE; } else if (mod_info->child_mapped_addr[i] == (void *)self->first_line.start_addr) { mod_info->next_addr = mod_info->child_mapped_addr[i]; } if (mod_info->addr && mod_info->next_addr) break; } ASSERT_TRUE(mod_info->addr && mod_info->next_addr); signal_state(mod_info, PARENT_READY); } FIXTURE_TEARDOWN(proc_maps_race) { int status; stop_vma_modifier(self->mod_info); free(self->page2.data); free(self->page1.data); for (int i = 0; i < self->vma_count; i++) munmap(self->mod_info->child_mapped_addr[i], self->page_size); close(self->maps_fd); waitpid(self->pid, &status, 0); munmap(self->mod_info, self->shared_mem_size); } TEST_F(proc_maps_race, test_maps_tearing_from_split) { struct vma_modifier_info *mod_info = self->mod_info; struct line_content split_last_line; struct line_content split_first_line; struct line_content restored_last_line; struct line_content restored_first_line; wait_for_state(mod_info, SETUP_READY); /* re-read the file to avoid using stale data from previous test */ ASSERT_TRUE(read_boundary_lines(self, &self->last_line, &self->first_line)); mod_info->vma_modify = split_vma; mod_info->vma_restore = merge_vma; mod_info->vma_mod_check = check_split_result; report_test_start("Tearing from split", self->verbose); ASSERT_TRUE(capture_mod_pattern(self, &split_last_line, &split_first_line, &restored_last_line, &restored_first_line)); /* Now start concurrent modifications for self->duration_sec */ signal_state(mod_info, TEST_READY); struct line_content new_last_line; struct line_content new_first_line; struct timespec start_ts, end_ts; clock_gettime(CLOCK_MONOTONIC_COARSE, &start_ts); start_test_loop(&start_ts, self->verbose); do { bool last_line_changed; bool first_line_changed; ASSERT_TRUE(read_boundary_lines(self, &new_last_line, &new_first_line)); /* Check if we read vmas after split */ if (!strcmp(new_last_line.text, split_last_line.text)) { /* * The vmas should be consistent with split results, * however if vma was concurrently restored after a * split, it can be reported twice (first the original * split one, then the same vma but extended after the * merge) because we found it as the next vma again. * In that case new first line will be the same as the * last restored line. */ ASSERT_FALSE(print_boundaries_on( strcmp(new_first_line.text, split_first_line.text) && strcmp(new_first_line.text, restored_last_line.text), "Split result invalid", self)); } else { /* The vmas should be consistent with merge results */ ASSERT_FALSE(print_boundaries_on( strcmp(new_last_line.text, restored_last_line.text), "Merge result invalid", self)); ASSERT_FALSE(print_boundaries_on( strcmp(new_first_line.text, restored_first_line.text), "Merge result invalid", self)); } /* * First and last lines should change in unison. If the last * line changed then the first line should change as well and * vice versa. */ last_line_changed = strcmp(new_last_line.text, self->last_line.text) != 0; first_line_changed = strcmp(new_first_line.text, self->first_line.text) != 0; ASSERT_EQ(last_line_changed, first_line_changed); clock_gettime(CLOCK_MONOTONIC_COARSE, &end_ts); end_test_iteration(&end_ts, self->verbose); } while (end_ts.tv_sec - start_ts.tv_sec < self->duration_sec); end_test_loop(self->verbose); /* Signal the modifyer thread to stop and wait until it exits */ signal_state(mod_info, TEST_DONE); } TEST_F(proc_maps_race, test_maps_tearing_from_resize) { struct vma_modifier_info *mod_info = self->mod_info; struct line_content shrunk_last_line; struct line_content shrunk_first_line; struct line_content restored_last_line; struct line_content restored_first_line; wait_for_state(mod_info, SETUP_READY); /* re-read the file to avoid using stale data from previous test */ ASSERT_TRUE(read_boundary_lines(self, &self->last_line, &self->first_line)); mod_info->vma_modify = shrink_vma; mod_info->vma_restore = expand_vma; mod_info->vma_mod_check = check_shrink_result; report_test_start("Tearing from resize", self->verbose); ASSERT_TRUE(capture_mod_pattern(self, &shrunk_last_line, &shrunk_first_line, &restored_last_line, &restored_first_line)); /* Now start concurrent modifications for self->duration_sec */ signal_state(mod_info, TEST_READY); struct line_content new_last_line; struct line_content new_first_line; struct timespec start_ts, end_ts; clock_gettime(CLOCK_MONOTONIC_COARSE, &start_ts); start_test_loop(&start_ts, self->verbose); do { ASSERT_TRUE(read_boundary_lines(self, &new_last_line, &new_first_line)); /* Check if we read vmas after shrinking it */ if (!strcmp(new_last_line.text, shrunk_last_line.text)) { /* * The vmas should be consistent with shrunk results, * however if the vma was concurrently restored, it * can be reported twice (first as shrunk one, then * as restored one) because we found it as the next vma * again. In that case new first line will be the same * as the last restored line. */ ASSERT_FALSE(print_boundaries_on( strcmp(new_first_line.text, shrunk_first_line.text) && strcmp(new_first_line.text, restored_last_line.text), "Shrink result invalid", self)); } else { /* The vmas should be consistent with the original/resored state */ ASSERT_FALSE(print_boundaries_on( strcmp(new_last_line.text, restored_last_line.text), "Expand result invalid", self)); ASSERT_FALSE(print_boundaries_on( strcmp(new_first_line.text, restored_first_line.text), "Expand result invalid", self)); } clock_gettime(CLOCK_MONOTONIC_COARSE, &end_ts); end_test_iteration(&end_ts, self->verbose); } while (end_ts.tv_sec - start_ts.tv_sec < self->duration_sec); end_test_loop(self->verbose); /* Signal the modifyer thread to stop and wait until it exits */ signal_state(mod_info, TEST_DONE); } TEST_F(proc_maps_race, test_maps_tearing_from_remap) { struct vma_modifier_info *mod_info = self->mod_info; struct line_content remapped_last_line; struct line_content remapped_first_line; struct line_content restored_last_line; struct line_content restored_first_line; wait_for_state(mod_info, SETUP_READY); /* re-read the file to avoid using stale data from previous test */ ASSERT_TRUE(read_boundary_lines(self, &self->last_line, &self->first_line)); mod_info->vma_modify = remap_vma; mod_info->vma_restore = patch_vma; mod_info->vma_mod_check = check_remap_result; report_test_start("Tearing from remap", self->verbose); ASSERT_TRUE(capture_mod_pattern(self, &remapped_last_line, &remapped_first_line, &restored_last_line, &restored_first_line)); /* Now start concurrent modifications for self->duration_sec */ signal_state(mod_info, TEST_READY); struct line_content new_last_line; struct line_content new_first_line; struct timespec start_ts, end_ts; clock_gettime(CLOCK_MONOTONIC_COARSE, &start_ts); start_test_loop(&start_ts, self->verbose); do { ASSERT_TRUE(read_boundary_lines(self, &new_last_line, &new_first_line)); /* Check if we read vmas after remapping it */ if (!strcmp(new_last_line.text, remapped_last_line.text)) { /* * The vmas should be consistent with remap results, * however if the vma was concurrently restored, it * can be reported twice (first as split one, then * as restored one) because we found it as the next vma * again. In that case new first line will be the same * as the last restored line. */ ASSERT_FALSE(print_boundaries_on( strcmp(new_first_line.text, remapped_first_line.text) && strcmp(new_first_line.text, restored_last_line.text), "Remap result invalid", self)); } else { /* The vmas should be consistent with the original/resored state */ ASSERT_FALSE(print_boundaries_on( strcmp(new_last_line.text, restored_last_line.text), "Remap restore result invalid", self)); ASSERT_FALSE(print_boundaries_on( strcmp(new_first_line.text, restored_first_line.text), "Remap restore result invalid", self)); } clock_gettime(CLOCK_MONOTONIC_COARSE, &end_ts); end_test_iteration(&end_ts, self->verbose); } while (end_ts.tv_sec - start_ts.tv_sec < self->duration_sec); end_test_loop(self->verbose); /* Signal the modifyer thread to stop and wait until it exits */ signal_state(mod_info, TEST_DONE); } TEST_HARNESS_MAIN
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