// SPDX-License-Identifier: GPL-2.0 /* * Copyright 2019, Nick Piggin, Gautham R. Shenoy, Aneesh Kumar K.V, IBM Corp. */ /* * * Test tlbie/mtpidr race. We have 4 threads doing flush/load/compare/store * sequence in a loop. The same threads also rung a context switch task * that does sched_yield() in loop. * * The snapshot thread mark the mmap area PROT_READ in between, make a copy * and copy it back to the original area. This helps us to detect if any * store continued to happen after we marked the memory PROT_READ. */ #define _GNU_SOURCE #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static inline void dcbf(volatile unsigned int *addr) { __asm__ __volatile__ ("dcbf %y0; sync" : : "Z"(*(unsigned char *)addr) : "memory"); } static void err_msg(char *msg) { time_t now; time(&now); printf("=================================\n"); printf(" Error: %s\n", msg); printf(" %s", ctime(&now)); printf("=================================\n"); exit(1); } static char *map1; static char *map2; static pid_t rim_process_pid; /* * A "rim-sequence" is defined to be the sequence of the following * operations performed on a memory word: * 1) FLUSH the contents of that word. * 2) LOAD the contents of that word. * 3) COMPARE the contents of that word with the content that was * previously stored at that word * 4) STORE new content into that word. * * The threads in this test that perform the rim-sequence are termed * as rim_threads. */ /* * A "corruption" is defined to be the failed COMPARE operation in a * rim-sequence. * * A rim_thread that detects a corruption informs about it to all the * other rim_threads, and the mem_snapshot thread. */ static volatile unsigned int corruption_found; /* * This defines the maximum number of rim_threads in this test. * * The THREAD_ID_BITS denote the number of bits required * to represent the thread_ids [0..MAX_THREADS - 1]. * We are being a bit paranoid here and set it to 8 bits, * though 6 bits suffice. * */ #define MAX_THREADS 64 #define THREAD_ID_BITS 8 #define THREAD_ID_MASK ((1 << THREAD_ID_BITS) - 1) static unsigned int rim_thread_ids[MAX_THREADS]; static pthread_t rim_threads[MAX_THREADS]; /* * Each rim_thread works on an exclusive "chunk" of size * RIM_CHUNK_SIZE. * * The ith rim_thread works on the ith chunk. * * The ith chunk begins at * map1 + (i * RIM_CHUNK_SIZE) */ #define RIM_CHUNK_SIZE 1024 #define BITS_PER_BYTE 8 #define WORD_SIZE (sizeof(unsigned int)) #define WORD_BITS (WORD_SIZE * BITS_PER_BYTE) #define WORDS_PER_CHUNK (RIM_CHUNK_SIZE/WORD_SIZE) static inline char *compute_chunk_start_addr(unsigned int thread_id) { char *chunk_start; chunk_start = (char *)((unsigned long)map1 + (thread_id * RIM_CHUNK_SIZE)); return chunk_start; } /* * The "word-offset" of a word-aligned address inside a chunk, is * defined to be the number of words that precede the address in that * chunk. * * WORD_OFFSET_BITS denote the number of bits required to represent * the word-offsets of all the word-aligned addresses of a chunk. */ #define WORD_OFFSET_BITS (__builtin_ctz(WORDS_PER_CHUNK)) #define WORD_OFFSET_MASK ((1 << WORD_OFFSET_BITS) - 1) static inline unsigned int compute_word_offset(char *start, unsigned int *addr) { unsigned int delta_bytes, ret; delta_bytes = (unsigned long)addr - (unsigned long)start; ret = delta_bytes/WORD_SIZE; return ret; } /* * A "sweep" is defined to be the sequential execution of the * rim-sequence by a rim_thread on its chunk one word at a time, * starting from the first word of its chunk and ending with the last * word of its chunk. * * Each sweep of a rim_thread is uniquely identified by a sweep_id. * SWEEP_ID_BITS denote the number of bits required to represent * the sweep_ids of rim_threads. * * As to why SWEEP_ID_BITS are computed as a function of THREAD_ID_BITS, * WORD_OFFSET_BITS, and WORD_BITS, see the "store-pattern" below. */ #define SWEEP_ID_BITS (WORD_BITS - (THREAD_ID_BITS + WORD_OFFSET_BITS)) #define SWEEP_ID_MASK ((1 << SWEEP_ID_BITS) - 1) /* * A "store-pattern" is the word-pattern that is stored into a word * location in the 4)STORE step of the rim-sequence. * * In the store-pattern, we shall encode: * * - The thread-id of the rim_thread performing the store * (The most significant THREAD_ID_BITS) * * - The word-offset of the address into which the store is being * performed (The next WORD_OFFSET_BITS) * * - The sweep_id of the current sweep in which the store is * being performed. (The lower SWEEP_ID_BITS) * * Store Pattern: 32 bits * |------------------|--------------------|---------------------------------| * | Thread id | Word offset | sweep_id | * |------------------|--------------------|---------------------------------| * THREAD_ID_BITS WORD_OFFSET_BITS SWEEP_ID_BITS * * In the store pattern, the (Thread-id + Word-offset) uniquely identify the * address to which the store is being performed i.e, * address == map1 + * (Thread-id * RIM_CHUNK_SIZE) + (Word-offset * WORD_SIZE) * * And the sweep_id in the store pattern identifies the time when the * store was performed by the rim_thread. * * We shall use this property in the 3)COMPARE step of the * rim-sequence. */ #define SWEEP_ID_SHIFT 0 #define WORD_OFFSET_SHIFT (SWEEP_ID_BITS) #define THREAD_ID_SHIFT (WORD_OFFSET_BITS + SWEEP_ID_BITS) /* * Compute the store pattern for a given thread with id @tid, at * location @addr in the sweep identified by @sweep_id */ static inline unsigned int compute_store_pattern(unsigned int tid, unsigned int *addr, unsigned int sweep_id) { unsigned int ret = 0; char *start = compute_chunk_start_addr(tid); unsigned int word_offset = compute_word_offset(start, addr); ret += (tid & THREAD_ID_MASK) << THREAD_ID_SHIFT; ret += (word_offset & WORD_OFFSET_MASK) << WORD_OFFSET_SHIFT; ret += (sweep_id & SWEEP_ID_MASK) << SWEEP_ID_SHIFT; return ret; } /* Extract the thread-id from the given store-pattern */ static inline unsigned int extract_tid(unsigned int pattern) { unsigned int ret; ret = (pattern >> THREAD_ID_SHIFT) & THREAD_ID_MASK; return ret; } /* Extract the word-offset from the given store-pattern */ static inline unsigned int extract_word_offset(unsigned int pattern) { unsigned int ret; ret = (pattern >> WORD_OFFSET_SHIFT) & WORD_OFFSET_MASK; return ret; } /* Extract the sweep-id from the given store-pattern */ static inline unsigned int extract_sweep_id(unsigned int pattern) { unsigned int ret; ret = (pattern >> SWEEP_ID_SHIFT) & SWEEP_ID_MASK; return ret; } /************************************************************ * * * Logging the output of the verification * * * ************************************************************/ #define LOGDIR_NAME_SIZE 100 static char logdir[LOGDIR_NAME_SIZE]; static FILE *fp[MAX_THREADS]; static const char logfilename[] ="Thread-%02d-Chunk"; static inline void start_verification_log(unsigned int tid, unsigned int *addr, unsigned int cur_sweep_id, unsigned int prev_sweep_id) { FILE *f; char logfile[30]; char path[LOGDIR_NAME_SIZE + 30]; char separator[2] = "/"; char *chunk_start = compute_chunk_start_addr(tid); unsigned int size = RIM_CHUNK_SIZE; sprintf(logfile, logfilename, tid); strcpy(path, logdir); strcat(path, separator); strcat(path, logfile); f = fopen(path, "w"); if (!f) { err_msg("Unable to create logfile\n"); } fp[tid] = f; fprintf(f, "----------------------------------------------------------\n"); fprintf(f, "PID = %d\n", rim_process_pid); fprintf(f, "Thread id = %02d\n", tid); fprintf(f, "Chunk Start Addr = 0x%016lx\n", (unsigned long)chunk_start); fprintf(f, "Chunk Size = %d\n", size); fprintf(f, "Next Store Addr = 0x%016lx\n", (unsigned long)addr); fprintf(f, "Current sweep-id = 0x%08x\n", cur_sweep_id); fprintf(f, "Previous sweep-id = 0x%08x\n", prev_sweep_id); fprintf(f, "----------------------------------------------------------\n"); } static inline void log_anamoly(unsigned int tid, unsigned int *addr, unsigned int expected, unsigned int observed) { FILE *f = fp[tid]; fprintf(f, "Thread %02d: Addr 0x%lx: Expected 0x%x, Observed 0x%x\n", tid, (unsigned long)addr, expected, observed); fprintf(f, "Thread %02d: Expected Thread id = %02d\n", tid, extract_tid(expected)); fprintf(f, "Thread %02d: Observed Thread id = %02d\n", tid, extract_tid(observed)); fprintf(f, "Thread %02d: Expected Word offset = %03d\n", tid, extract_word_offset(expected)); fprintf(f, "Thread %02d: Observed Word offset = %03d\n", tid, extract_word_offset(observed)); fprintf(f, "Thread %02d: Expected sweep-id = 0x%x\n", tid, extract_sweep_id(expected)); fprintf(f, "Thread %02d: Observed sweep-id = 0x%x\n", tid, extract_sweep_id(observed)); fprintf(f, "----------------------------------------------------------\n"); } static inline void end_verification_log(unsigned int tid, unsigned nr_anamolies) { FILE *f = fp[tid]; char logfile[30]; char path[LOGDIR_NAME_SIZE + 30]; char separator[] = "/"; fclose(f); if (nr_anamolies == 0) { remove(path); return; } sprintf(logfile, logfilename, tid); strcpy(path, logdir); strcat(path, separator); strcat(path, logfile); printf("Thread %02d chunk has %d corrupted words. For details check %s\n", tid, nr_anamolies, path); } /* * When a COMPARE step of a rim-sequence fails, the rim_thread informs * everyone else via the shared_memory pointed to by * corruption_found variable. On seeing this, every thread verifies the * content of its chunk as follows. * * Suppose a thread identified with @tid was about to store (but not * yet stored) to @next_store_addr in its current sweep identified * @cur_sweep_id. Let @prev_sweep_id indicate the previous sweep_id. * * This implies that for all the addresses @addr < @next_store_addr, * Thread @tid has already performed a store as part of its current * sweep. Hence we expect the content of such @addr to be: * |-------------------------------------------------| * | tid | word_offset(addr) | cur_sweep_id | * |-------------------------------------------------| * * Since Thread @tid is yet to perform stores on address * @next_store_addr and above, we expect the content of such an * address @addr to be: * |-------------------------------------------------| * | tid | word_offset(addr) | prev_sweep_id | * |-------------------------------------------------| * * The verifier function @verify_chunk does this verification and logs * any anamolies that it finds. */ static void verify_chunk(unsigned int tid, unsigned int *next_store_addr, unsigned int cur_sweep_id, unsigned int prev_sweep_id) { unsigned int *iter_ptr; unsigned int size = RIM_CHUNK_SIZE; unsigned int expected; unsigned int observed; char *chunk_start = compute_chunk_start_addr(tid); int nr_anamolies = 0; start_verification_log(tid, next_store_addr, cur_sweep_id, prev_sweep_id); for (iter_ptr = (unsigned int *)chunk_start; (unsigned long)iter_ptr < (unsigned long)chunk_start + size; iter_ptr++) { unsigned int expected_sweep_id; if (iter_ptr < next_store_addr) { expected_sweep_id = cur_sweep_id; } else { expected_sweep_id = prev_sweep_id; } expected = compute_store_pattern(tid, iter_ptr, expected_sweep_id); dcbf((volatile unsigned int*)iter_ptr); //Flush before reading observed = *iter_ptr; if (observed != expected) { nr_anamolies++; log_anamoly(tid, iter_ptr, expected, observed); } } end_verification_log(tid, nr_anamolies); } static void set_pthread_cpu(pthread_t th, int cpu) { cpu_set_t run_cpu_mask; struct sched_param param; CPU_ZERO(&run_cpu_mask); CPU_SET(cpu, &run_cpu_mask); pthread_setaffinity_np(th, sizeof(cpu_set_t), &run_cpu_mask); param.sched_priority = 1; if (0 && sched_setscheduler(0, SCHED_FIFO, ¶m) == -1) { /* haven't reproduced with this setting, it kills random preemption which may be a factor */ fprintf(stderr, "could not set SCHED_FIFO, run as root?\n"); } } static void set_mycpu(int cpu) { cpu_set_t run_cpu_mask; struct sched_param param; CPU_ZERO(&run_cpu_mask); CPU_SET(cpu, &run_cpu_mask); sched_setaffinity(0, sizeof(cpu_set_t), &run_cpu_mask); param.sched_priority = 1; if (0 && sched_setscheduler(0, SCHED_FIFO, ¶m) == -1) { fprintf(stderr, "could not set SCHED_FIFO, run as root?\n"); } } static volatile int segv_wait; static void segv_handler(int signo, siginfo_t *info, void *extra) { while (segv_wait) { sched_yield(); } } static void set_segv_handler(void) { struct sigaction sa; sa.sa_flags = SA_SIGINFO; sa.sa_sigaction = segv_handler; if (sigaction(SIGSEGV, &sa, NULL) == -1) { perror("sigaction"); exit(EXIT_FAILURE); } } int timeout = 0; /* * This function is executed by every rim_thread. * * This function performs sweeps over the exclusive chunks of the * rim_threads executing the rim-sequence one word at a time. */ static void *rim_fn(void *arg) { unsigned int tid = *((unsigned int *)arg); int size = RIM_CHUNK_SIZE; char *chunk_start = compute_chunk_start_addr(tid); unsigned int prev_sweep_id; unsigned int cur_sweep_id = 0; /* word access */ unsigned int pattern = cur_sweep_id; unsigned int *pattern_ptr = &pattern; unsigned int *w_ptr, read_data; set_segv_handler(); /* * Let us initialize the chunk: * * Each word-aligned address addr in the chunk, * is initialized to : * |-------------------------------------------------| * | tid | word_offset(addr) | 0 | * |-------------------------------------------------| */ for (w_ptr = (unsigned int *)chunk_start; (unsigned long)w_ptr < (unsigned long)(chunk_start) + size; w_ptr++) { *pattern_ptr = compute_store_pattern(tid, w_ptr, cur_sweep_id); *w_ptr = *pattern_ptr; } while (!corruption_found && !timeout) { prev_sweep_id = cur_sweep_id; cur_sweep_id = cur_sweep_id + 1; for (w_ptr = (unsigned int *)chunk_start; (unsigned long)w_ptr < (unsigned long)(chunk_start) + size; w_ptr++) { unsigned int old_pattern; /* * Compute the pattern that we would have * stored at this location in the previous * sweep. */ old_pattern = compute_store_pattern(tid, w_ptr, prev_sweep_id); /* * FLUSH:Ensure that we flush the contents of * the cache before loading */ dcbf((volatile unsigned int*)w_ptr); //Flush /* LOAD: Read the value */ read_data = *w_ptr; //Load /* * COMPARE: Is it the same as what we had stored * in the previous sweep ? It better be! */ if (read_data != old_pattern) { /* No it isn't! Tell everyone */ corruption_found = 1; } /* * Before performing a store, let us check if * any rim_thread has found a corruption. */ if (corruption_found || timeout) { /* * Yes. Someone (including us!) has found * a corruption :( * * Let us verify that our chunk is * correct. */ /* But first, let us allow the dust to settle down! */ verify_chunk(tid, w_ptr, cur_sweep_id, prev_sweep_id); return 0; } /* * Compute the new pattern that we are going * to write to this location */ *pattern_ptr = compute_store_pattern(tid, w_ptr, cur_sweep_id); /* * STORE: Now let us write this pattern into * the location */ *w_ptr = *pattern_ptr; } } return NULL; } static unsigned long start_cpu = 0; static unsigned long nrthreads = 4; static pthread_t mem_snapshot_thread; static void *mem_snapshot_fn(void *arg) { int page_size = getpagesize(); size_t size = page_size; void *tmp = malloc(size); while (!corruption_found && !timeout) { /* Stop memory migration once corruption is found */ segv_wait = 1; mprotect(map1, size, PROT_READ); /* * Load from the working alias (map1). Loading from map2 * also fails. */ memcpy(tmp, map1, size); /* * Stores must go via map2 which has write permissions, but * the corrupted data tends to be seen in the snapshot buffer, * so corruption does not appear to be introduced at the * copy-back via map2 alias here. */ memcpy(map2, tmp, size); /* * Before releasing other threads, must ensure the copy * back to */ asm volatile("sync" ::: "memory"); mprotect(map1, size, PROT_READ|PROT_WRITE); asm volatile("sync" ::: "memory"); segv_wait = 0; usleep(1); /* This value makes a big difference */ } return 0; } void alrm_sighandler(int sig) { timeout = 1; } int main(int argc, char *argv[]) { int c; int page_size = getpagesize(); time_t now; int i, dir_error; pthread_attr_t attr; key_t shm_key = (key_t) getpid(); int shmid, run_time = 20 * 60; struct sigaction sa_alrm; snprintf(logdir, LOGDIR_NAME_SIZE, "/tmp/logdir-%u", (unsigned int)getpid()); while ((c = getopt(argc, argv, "r:hn:l:t:")) != -1) { switch(c) { case 'r': start_cpu = strtoul(optarg, NULL, 10); break; case 'h': printf("%s [-r ] [-n ] [-l ] [-t ]\n", argv[0]); exit(0); break; case 'n': nrthreads = strtoul(optarg, NULL, 10); break; case 'l': strncpy(logdir, optarg, LOGDIR_NAME_SIZE - 1); break; case 't': run_time = strtoul(optarg, NULL, 10); break; default: printf("invalid option\n"); exit(0); break; } } if (nrthreads > MAX_THREADS) nrthreads = MAX_THREADS; shmid = shmget(shm_key, page_size, IPC_CREAT|0666); if (shmid < 0) { err_msg("Failed shmget\n"); } map1 = shmat(shmid, NULL, 0); if (map1 == (void *) -1) { err_msg("Failed shmat"); } map2 = shmat(shmid, NULL, 0); if (map2 == (void *) -1) { err_msg("Failed shmat"); } dir_error = mkdir(logdir, 0755); if (dir_error) { err_msg("Failed mkdir"); } printf("start_cpu list:%lu\n", start_cpu); printf("number of worker threads:%lu + 1 snapshot thread\n", nrthreads); printf("Allocated address:0x%016lx + secondary map:0x%016lx\n", (unsigned long)map1, (unsigned long)map2); printf("logdir at : %s\n", logdir); printf("Timeout: %d seconds\n", run_time); time(&now); printf("=================================\n"); printf(" Starting Test\n"); printf(" %s", ctime(&now)); printf("=================================\n"); for (i = 0; i < nrthreads; i++) { if (1 && !fork()) { prctl(PR_SET_PDEATHSIG, SIGKILL); set_mycpu(start_cpu + i); for (;;) sched_yield(); exit(0); } } sa_alrm.sa_handler = &alrm_sighandler; sigemptyset(&sa_alrm.sa_mask); sa_alrm.sa_flags = 0; if (sigaction(SIGALRM, &sa_alrm, 0) == -1) { err_msg("Failed signal handler registration\n"); } alarm(run_time); pthread_attr_init(&attr); for (i = 0; i < nrthreads; i++) { rim_thread_ids[i] = i; pthread_create(&rim_threads[i], &attr, rim_fn, &rim_thread_ids[i]); set_pthread_cpu(rim_threads[i], start_cpu + i); } pthread_create(&mem_snapshot_thread, &attr, mem_snapshot_fn, map1); set_pthread_cpu(mem_snapshot_thread, start_cpu + i); pthread_join(mem_snapshot_thread, NULL); for (i = 0; i < nrthreads; i++) { pthread_join(rim_threads[i], NULL); } if (!timeout) { time(&now); printf("=================================\n"); printf(" Data Corruption Detected\n"); printf(" %s", ctime(&now)); printf(" See logfiles in %s\n", logdir); printf("=================================\n"); return 1; } return 0; }