// SPDX-License-Identifier: GPL-2.0 /* * Copyright 2020 Google LLC */ #define _GNU_SOURCE #include #include #include #include #include #include #include #include "../kselftest.h" #define EXPECT_SUCCESS 0 #define EXPECT_FAILURE 1 #define NON_OVERLAPPING 0 #define OVERLAPPING 1 #define NS_PER_SEC 1000000000ULL #define VALIDATION_DEFAULT_THRESHOLD 4 /* 4MB */ #define VALIDATION_NO_THRESHOLD 0 /* Verify the entire region */ #define ARRAY_SIZE(x) (sizeof(x) / sizeof((x)[0])) #define MIN(X, Y) ((X) < (Y) ? (X) : (Y)) struct config { unsigned long long src_alignment; unsigned long long dest_alignment; unsigned long long region_size; int overlapping; }; struct test { const char *name; struct config config; int expect_failure; }; enum { _1KB = 1ULL << 10, /* 1KB -> not page aligned */ _4KB = 4ULL << 10, _8KB = 8ULL << 10, _1MB = 1ULL << 20, _2MB = 2ULL << 20, _4MB = 4ULL << 20, _1GB = 1ULL << 30, _2GB = 2ULL << 30, PMD = _2MB, PUD = _1GB, }; #define PTE page_size #define MAKE_TEST(source_align, destination_align, size, \ overlaps, should_fail, test_name) \ (struct test){ \ .name = test_name, \ .config = { \ .src_alignment = source_align, \ .dest_alignment = destination_align, \ .region_size = size, \ .overlapping = overlaps, \ }, \ .expect_failure = should_fail \ } /* * Returns false if the requested remap region overlaps with an * existing mapping (e.g text, stack) else returns true. */ static bool is_remap_region_valid(void *addr, unsigned long long size) { void *remap_addr = NULL; bool ret = true; /* Use MAP_FIXED_NOREPLACE flag to ensure region is not mapped */ remap_addr = mmap(addr, size, PROT_READ | PROT_WRITE, MAP_FIXED_NOREPLACE | MAP_ANONYMOUS | MAP_SHARED, -1, 0); if (remap_addr == MAP_FAILED) { if (errno == EEXIST) ret = false; } else { munmap(remap_addr, size); } return ret; } /* Returns mmap_min_addr sysctl tunable from procfs */ static unsigned long long get_mmap_min_addr(void) { FILE *fp; int n_matched; static unsigned long long addr; if (addr) return addr; fp = fopen("/proc/sys/vm/mmap_min_addr", "r"); if (fp == NULL) { ksft_print_msg("Failed to open /proc/sys/vm/mmap_min_addr: %s\n", strerror(errno)); exit(KSFT_SKIP); } n_matched = fscanf(fp, "%llu", &addr); if (n_matched != 1) { ksft_print_msg("Failed to read /proc/sys/vm/mmap_min_addr: %s\n", strerror(errno)); fclose(fp); exit(KSFT_SKIP); } fclose(fp); return addr; } /* * Returns the start address of the mapping on success, else returns * NULL on failure. */ static void *get_source_mapping(struct config c) { unsigned long long addr = 0ULL; void *src_addr = NULL; unsigned long long mmap_min_addr; mmap_min_addr = get_mmap_min_addr(); retry: addr += c.src_alignment; if (addr < mmap_min_addr) goto retry; src_addr = mmap((void *) addr, c.region_size, PROT_READ | PROT_WRITE, MAP_FIXED_NOREPLACE | MAP_ANONYMOUS | MAP_SHARED, -1, 0); if (src_addr == MAP_FAILED) { if (errno == EPERM || errno == EEXIST) goto retry; goto error; } /* * Check that the address is aligned to the specified alignment. * Addresses which have alignments that are multiples of that * specified are not considered valid. For instance, 1GB address is * 2MB-aligned, however it will not be considered valid for a * requested alignment of 2MB. This is done to reduce coincidental * alignment in the tests. */ if (((unsigned long long) src_addr & (c.src_alignment - 1)) || !((unsigned long long) src_addr & c.src_alignment)) { munmap(src_addr, c.region_size); goto retry; } if (!src_addr) goto error; return src_addr; error: ksft_print_msg("Failed to map source region: %s\n", strerror(errno)); return NULL; } /* Returns the time taken for the remap on success else returns -1. */ static long long remap_region(struct config c, unsigned int threshold_mb, char pattern_seed) { void *addr, *src_addr, *dest_addr; unsigned long long i; struct timespec t_start = {0, 0}, t_end = {0, 0}; long long start_ns, end_ns, align_mask, ret, offset; unsigned long long threshold; if (threshold_mb == VALIDATION_NO_THRESHOLD) threshold = c.region_size; else threshold = MIN(threshold_mb * _1MB, c.region_size); src_addr = get_source_mapping(c); if (!src_addr) { ret = -1; goto out; } /* Set byte pattern */ srand(pattern_seed); for (i = 0; i < threshold; i++) memset((char *) src_addr + i, (char) rand(), 1); /* Mask to zero out lower bits of address for alignment */ align_mask = ~(c.dest_alignment - 1); /* Offset of destination address from the end of the source region */ offset = (c.overlapping) ? -c.dest_alignment : c.dest_alignment; addr = (void *) (((unsigned long long) src_addr + c.region_size + offset) & align_mask); /* See comment in get_source_mapping() */ if (!((unsigned long long) addr & c.dest_alignment)) addr = (void *) ((unsigned long long) addr | c.dest_alignment); /* Don't destroy existing mappings unless expected to overlap */ while (!is_remap_region_valid(addr, c.region_size) && !c.overlapping) { /* Check for unsigned overflow */ if (addr + c.dest_alignment < addr) { ksft_print_msg("Couldn't find a valid region to remap to\n"); ret = -1; goto out; } addr += c.dest_alignment; } clock_gettime(CLOCK_MONOTONIC, &t_start); dest_addr = mremap(src_addr, c.region_size, c.region_size, MREMAP_MAYMOVE|MREMAP_FIXED, (char *) addr); clock_gettime(CLOCK_MONOTONIC, &t_end); if (dest_addr == MAP_FAILED) { ksft_print_msg("mremap failed: %s\n", strerror(errno)); ret = -1; goto clean_up_src; } /* Verify byte pattern after remapping */ srand(pattern_seed); for (i = 0; i < threshold; i++) { char c = (char) rand(); if (((char *) dest_addr)[i] != c) { ksft_print_msg("Data after remap doesn't match at offset %d\n", i); ksft_print_msg("Expected: %#x\t Got: %#x\n", c & 0xff, ((char *) dest_addr)[i] & 0xff); ret = -1; goto clean_up_dest; } } start_ns = t_start.tv_sec * NS_PER_SEC + t_start.tv_nsec; end_ns = t_end.tv_sec * NS_PER_SEC + t_end.tv_nsec; ret = end_ns - start_ns; /* * Since the destination address is specified using MREMAP_FIXED, subsequent * mremap will unmap any previous mapping at the address range specified by * dest_addr and region_size. This significantly affects the remap time of * subsequent tests. So we clean up mappings after each test. */ clean_up_dest: munmap(dest_addr, c.region_size); clean_up_src: munmap(src_addr, c.region_size); out: return ret; } static void run_mremap_test_case(struct test test_case, int *failures, unsigned int threshold_mb, unsigned int pattern_seed) { long long remap_time = remap_region(test_case.config, threshold_mb, pattern_seed); if (remap_time < 0) { if (test_case.expect_failure) ksft_test_result_pass("%s\n\tExpected mremap failure\n", test_case.name); else { ksft_test_result_fail("%s\n", test_case.name); *failures += 1; } } else { /* * Comparing mremap time is only applicable if entire region * was faulted in. */ if (threshold_mb == VALIDATION_NO_THRESHOLD || test_case.config.region_size <= threshold_mb * _1MB) ksft_test_result_pass("%s\n\tmremap time: %12lldns\n", test_case.name, remap_time); else ksft_test_result_pass("%s\n", test_case.name); } } static void usage(const char *cmd) { fprintf(stderr, "Usage: %s [[-t ] [-p ]]\n" "-t\t only validate threshold_mb of the remapped region\n" " \t if 0 is supplied no threshold is used; all tests\n" " \t are run and remapped regions validated fully.\n" " \t The default threshold used is 4MB.\n" "-p\t provide a seed to generate the random pattern for\n" " \t validating the remapped region.\n", cmd); } static int parse_args(int argc, char **argv, unsigned int *threshold_mb, unsigned int *pattern_seed) { const char *optstr = "t:p:"; int opt; while ((opt = getopt(argc, argv, optstr)) != -1) { switch (opt) { case 't': *threshold_mb = atoi(optarg); break; case 'p': *pattern_seed = atoi(optarg); break; default: usage(argv[0]); return -1; } } if (optind < argc) { usage(argv[0]); return -1; } return 0; } #define MAX_TEST 13 #define MAX_PERF_TEST 3 int main(int argc, char **argv) { int failures = 0; int i, run_perf_tests; unsigned int threshold_mb = VALIDATION_DEFAULT_THRESHOLD; unsigned int pattern_seed; struct test test_cases[MAX_TEST]; struct test perf_test_cases[MAX_PERF_TEST]; int page_size; time_t t; pattern_seed = (unsigned int) time(&t); if (parse_args(argc, argv, &threshold_mb, &pattern_seed) < 0) exit(EXIT_FAILURE); ksft_print_msg("Test configs:\n\tthreshold_mb=%u\n\tpattern_seed=%u\n\n", threshold_mb, pattern_seed); page_size = sysconf(_SC_PAGESIZE); /* Expected mremap failures */ test_cases[0] = MAKE_TEST(page_size, page_size, page_size, OVERLAPPING, EXPECT_FAILURE, "mremap - Source and Destination Regions Overlapping"); test_cases[1] = MAKE_TEST(page_size, page_size/4, page_size, NON_OVERLAPPING, EXPECT_FAILURE, "mremap - Destination Address Misaligned (1KB-aligned)"); test_cases[2] = MAKE_TEST(page_size/4, page_size, page_size, NON_OVERLAPPING, EXPECT_FAILURE, "mremap - Source Address Misaligned (1KB-aligned)"); /* Src addr PTE aligned */ test_cases[3] = MAKE_TEST(PTE, PTE, PTE * 2, NON_OVERLAPPING, EXPECT_SUCCESS, "8KB mremap - Source PTE-aligned, Destination PTE-aligned"); /* Src addr 1MB aligned */ test_cases[4] = MAKE_TEST(_1MB, PTE, _2MB, NON_OVERLAPPING, EXPECT_SUCCESS, "2MB mremap - Source 1MB-aligned, Destination PTE-aligned"); test_cases[5] = MAKE_TEST(_1MB, _1MB, _2MB, NON_OVERLAPPING, EXPECT_SUCCESS, "2MB mremap - Source 1MB-aligned, Destination 1MB-aligned"); /* Src addr PMD aligned */ test_cases[6] = MAKE_TEST(PMD, PTE, _4MB, NON_OVERLAPPING, EXPECT_SUCCESS, "4MB mremap - Source PMD-aligned, Destination PTE-aligned"); test_cases[7] = MAKE_TEST(PMD, _1MB, _4MB, NON_OVERLAPPING, EXPECT_SUCCESS, "4MB mremap - Source PMD-aligned, Destination 1MB-aligned"); test_cases[8] = MAKE_TEST(PMD, PMD, _4MB, NON_OVERLAPPING, EXPECT_SUCCESS, "4MB mremap - Source PMD-aligned, Destination PMD-aligned"); /* Src addr PUD aligned */ test_cases[9] = MAKE_TEST(PUD, PTE, _2GB, NON_OVERLAPPING, EXPECT_SUCCESS, "2GB mremap - Source PUD-aligned, Destination PTE-aligned"); test_cases[10] = MAKE_TEST(PUD, _1MB, _2GB, NON_OVERLAPPING, EXPECT_SUCCESS, "2GB mremap - Source PUD-aligned, Destination 1MB-aligned"); test_cases[11] = MAKE_TEST(PUD, PMD, _2GB, NON_OVERLAPPING, EXPECT_SUCCESS, "2GB mremap - Source PUD-aligned, Destination PMD-aligned"); test_cases[12] = MAKE_TEST(PUD, PUD, _2GB, NON_OVERLAPPING, EXPECT_SUCCESS, "2GB mremap - Source PUD-aligned, Destination PUD-aligned"); perf_test_cases[0] = MAKE_TEST(page_size, page_size, _1GB, NON_OVERLAPPING, EXPECT_SUCCESS, "1GB mremap - Source PTE-aligned, Destination PTE-aligned"); /* * mremap 1GB region - Page table level aligned time * comparison. */ perf_test_cases[1] = MAKE_TEST(PMD, PMD, _1GB, NON_OVERLAPPING, EXPECT_SUCCESS, "1GB mremap - Source PMD-aligned, Destination PMD-aligned"); perf_test_cases[2] = MAKE_TEST(PUD, PUD, _1GB, NON_OVERLAPPING, EXPECT_SUCCESS, "1GB mremap - Source PUD-aligned, Destination PUD-aligned"); run_perf_tests = (threshold_mb == VALIDATION_NO_THRESHOLD) || (threshold_mb * _1MB >= _1GB); ksft_set_plan(ARRAY_SIZE(test_cases) + (run_perf_tests ? ARRAY_SIZE(perf_test_cases) : 0)); for (i = 0; i < ARRAY_SIZE(test_cases); i++) run_mremap_test_case(test_cases[i], &failures, threshold_mb, pattern_seed); if (run_perf_tests) { ksft_print_msg("\n%s\n", "mremap HAVE_MOVE_PMD/PUD optimization time comparison for 1GB region:"); for (i = 0; i < ARRAY_SIZE(perf_test_cases); i++) run_mremap_test_case(perf_test_cases[i], &failures, threshold_mb, pattern_seed); } if (failures > 0) ksft_exit_fail(); else ksft_exit_pass(); }