/* SPDX-License-Identifier: LGPL-2.1+ */ #include #include #include #include #include "def.h" #include "fileio.h" #include "fs-util.h" #include "parse-util.h" #include "process-util.h" #include "raw-clone.h" #include "rm-rf.h" #include "string-util.h" #include "util.h" static void test_align_power2(void) { unsigned long i, p2; assert_se(ALIGN_POWER2(0) == 0); assert_se(ALIGN_POWER2(1) == 1); assert_se(ALIGN_POWER2(2) == 2); assert_se(ALIGN_POWER2(3) == 4); assert_se(ALIGN_POWER2(12) == 16); assert_se(ALIGN_POWER2(ULONG_MAX) == 0); assert_se(ALIGN_POWER2(ULONG_MAX - 1) == 0); assert_se(ALIGN_POWER2(ULONG_MAX - 1024) == 0); assert_se(ALIGN_POWER2(ULONG_MAX / 2) == ULONG_MAX / 2 + 1); assert_se(ALIGN_POWER2(ULONG_MAX + 1) == 0); for (i = 1; i < 131071; ++i) { for (p2 = 1; p2 < i; p2 <<= 1) /* empty */ ; assert_se(ALIGN_POWER2(i) == p2); } for (i = ULONG_MAX - 1024; i < ULONG_MAX; ++i) { for (p2 = 1; p2 && p2 < i; p2 <<= 1) /* empty */ ; assert_se(ALIGN_POWER2(i) == p2); } } static void test_max(void) { static const struct { int a; int b[CONST_MAX(10, 100)]; } val1 = { .a = CONST_MAX(10, 100), }; int d = 0; assert_cc(sizeof(val1.b) == sizeof(int) * 100); /* CONST_MAX returns (void) instead of a value if the passed arguments * are not of the same type or not constant expressions. */ assert_cc(__builtin_types_compatible_p(typeof(CONST_MAX(1, 10)), int)); assert_cc(__builtin_types_compatible_p(typeof(CONST_MAX(1, 1U)), void)); assert_se(val1.a == 100); assert_se(MAX(++d, 0) == 1); assert_se(d == 1); assert_cc(MAXSIZE(char[3], uint16_t) == 3); assert_cc(MAXSIZE(char[3], uint32_t) == 4); assert_cc(MAXSIZE(char, long) == sizeof(long)); assert_se(MAX(-5, 5) == 5); assert_se(MAX(5, 5) == 5); assert_se(MAX(MAX(1, MAX(2, MAX(3, 4))), 5) == 5); assert_se(MAX(MAX(1, MAX(2, MAX(3, 2))), 1) == 3); assert_se(MAX(MIN(1, MIN(2, MIN(3, 4))), 5) == 5); assert_se(MAX(MAX(1, MIN(2, MIN(3, 2))), 1) == 2); assert_se(LESS_BY(8, 4) == 4); assert_se(LESS_BY(8, 8) == 0); assert_se(LESS_BY(4, 8) == 0); assert_se(LESS_BY(16, LESS_BY(8, 4)) == 12); assert_se(LESS_BY(4, LESS_BY(8, 4)) == 0); assert_se(CLAMP(-5, 0, 1) == 0); assert_se(CLAMP(5, 0, 1) == 1); assert_se(CLAMP(5, -10, 1) == 1); assert_se(CLAMP(5, -10, 10) == 5); assert_se(CLAMP(CLAMP(0, -10, 10), CLAMP(-5, 10, 20), CLAMP(100, -5, 20)) == 10); } #pragma GCC diagnostic push #ifdef __clang__ # pragma GCC diagnostic ignored "-Waddress-of-packed-member" #endif static void test_container_of(void) { struct mytype { uint8_t pad1[3]; uint64_t v1; uint8_t pad2[2]; uint32_t v2; } _packed_ myval = { }; assert_cc(sizeof(myval) == 17); assert_se(container_of(&myval.v1, struct mytype, v1) == &myval); assert_se(container_of(&myval.v2, struct mytype, v2) == &myval); assert_se(container_of(&container_of(&myval.v2, struct mytype, v2)->v1, struct mytype, v1) == &myval); } #pragma GCC diagnostic pop static void test_div_round_up(void) { int div; /* basic tests */ assert_se(DIV_ROUND_UP(0, 8) == 0); assert_se(DIV_ROUND_UP(1, 8) == 1); assert_se(DIV_ROUND_UP(8, 8) == 1); assert_se(DIV_ROUND_UP(12, 8) == 2); assert_se(DIV_ROUND_UP(16, 8) == 2); /* test multiple evaluation */ div = 0; assert_se(DIV_ROUND_UP(div++, 8) == 0 && div == 1); assert_se(DIV_ROUND_UP(++div, 8) == 1 && div == 2); assert_se(DIV_ROUND_UP(8, div++) == 4 && div == 3); assert_se(DIV_ROUND_UP(8, ++div) == 2 && div == 4); /* overflow test with exact division */ assert_se(sizeof(0U) == 4); assert_se(0xfffffffaU % 10U == 0U); assert_se(0xfffffffaU / 10U == 429496729U); assert_se(DIV_ROUND_UP(0xfffffffaU, 10U) == 429496729U); assert_se((0xfffffffaU + 10U - 1U) / 10U == 0U); assert_se(0xfffffffaU / 10U + !!(0xfffffffaU % 10U) == 429496729U); /* overflow test with rounded division */ assert_se(0xfffffffdU % 10U == 3U); assert_se(0xfffffffdU / 10U == 429496729U); assert_se(DIV_ROUND_UP(0xfffffffdU, 10U) == 429496730U); assert_se((0xfffffffdU + 10U - 1U) / 10U == 0U); assert_se(0xfffffffdU / 10U + !!(0xfffffffdU % 10U) == 429496730U); } static void test_u64log2(void) { assert_se(u64log2(0) == 0); assert_se(u64log2(8) == 3); assert_se(u64log2(9) == 3); assert_se(u64log2(15) == 3); assert_se(u64log2(16) == 4); assert_se(u64log2(1024*1024) == 20); assert_se(u64log2(1024*1024+5) == 20); } static void test_protect_errno(void) { errno = 12; { PROTECT_ERRNO; errno = 11; } assert_se(errno == 12); } static void test_in_set(void) { assert_se(IN_SET(1, 1)); assert_se(IN_SET(1, 1, 2, 3, 4)); assert_se(IN_SET(2, 1, 2, 3, 4)); assert_se(IN_SET(3, 1, 2, 3, 4)); assert_se(IN_SET(4, 1, 2, 3, 4)); assert_se(!IN_SET(0, 1)); assert_se(!IN_SET(0, 1, 2, 3, 4)); } static void test_log2i(void) { assert_se(log2i(1) == 0); assert_se(log2i(2) == 1); assert_se(log2i(3) == 1); assert_se(log2i(4) == 2); assert_se(log2i(32) == 5); assert_se(log2i(33) == 5); assert_se(log2i(63) == 5); assert_se(log2i(INT_MAX) == sizeof(int)*8-2); } static void test_raw_clone(void) { pid_t parent, pid, pid2; parent = getpid(); log_info("before clone: getpid()→"PID_FMT, parent); assert_se(raw_getpid() == parent); pid = raw_clone(0); assert_se(pid >= 0); pid2 = raw_getpid(); log_info("raw_clone: "PID_FMT" getpid()→"PID_FMT" raw_getpid()→"PID_FMT, pid, getpid(), pid2); if (pid == 0) { assert_se(pid2 != parent); _exit(EXIT_SUCCESS); } else { int status; assert_se(pid2 == parent); waitpid(pid, &status, __WCLONE); assert_se(WIFEXITED(status) && WEXITSTATUS(status) == EXIT_SUCCESS); } errno = 0; assert_se(raw_clone(CLONE_FS|CLONE_NEWNS) == -1); assert_se(errno == EINVAL); } static void test_physical_memory(void) { uint64_t p; char buf[FORMAT_BYTES_MAX]; p = physical_memory(); assert_se(p > 0); assert_se(p < UINT64_MAX); assert_se(p % page_size() == 0); log_info("Memory: %s (%" PRIu64 ")", format_bytes(buf, sizeof(buf), p), p); } static void test_physical_memory_scale(void) { uint64_t p; p = physical_memory(); assert_se(physical_memory_scale(0, 100) == 0); assert_se(physical_memory_scale(100, 100) == p); log_info("Memory original: %" PRIu64, physical_memory()); log_info("Memory scaled by 50%%: %" PRIu64, physical_memory_scale(50, 100)); log_info("Memory divided by 2: %" PRIu64, physical_memory() / 2); log_info("Page size: %zu", page_size()); /* There might be an uneven number of pages, hence permit these calculations to be half a page off... */ assert_se(page_size()/2 + physical_memory_scale(50, 100) - p/2 <= page_size()); assert_se(physical_memory_scale(200, 100) == p*2); assert_se(physical_memory_scale(0, 1) == 0); assert_se(physical_memory_scale(1, 1) == p); assert_se(physical_memory_scale(2, 1) == p*2); assert_se(physical_memory_scale(0, 2) == 0); assert_se(page_size()/2 + physical_memory_scale(1, 2) - p/2 <= page_size()); assert_se(physical_memory_scale(2, 2) == p); assert_se(physical_memory_scale(4, 2) == p*2); assert_se(physical_memory_scale(0, UINT32_MAX) == 0); assert_se(physical_memory_scale(UINT32_MAX, UINT32_MAX) == p); /* overflow */ assert_se(physical_memory_scale(UINT64_MAX/4, UINT64_MAX) == UINT64_MAX); } static void test_system_tasks_max(void) { uint64_t t; t = system_tasks_max(); assert_se(t > 0); assert_se(t < UINT64_MAX); log_info("Max tasks: %" PRIu64, t); } static void test_system_tasks_max_scale(void) { uint64_t t; t = system_tasks_max(); assert_se(system_tasks_max_scale(0, 100) == 0); assert_se(system_tasks_max_scale(100, 100) == t); assert_se(system_tasks_max_scale(0, 1) == 0); assert_se(system_tasks_max_scale(1, 1) == t); assert_se(system_tasks_max_scale(2, 1) == 2*t); assert_se(system_tasks_max_scale(0, 2) == 0); assert_se(system_tasks_max_scale(1, 2) == t/2); assert_se(system_tasks_max_scale(2, 2) == t); assert_se(system_tasks_max_scale(3, 2) == (3*t)/2); assert_se(system_tasks_max_scale(4, 2) == t*2); assert_se(system_tasks_max_scale(0, UINT32_MAX) == 0); assert_se(system_tasks_max_scale((UINT32_MAX-1)/2, UINT32_MAX-1) == t/2); assert_se(system_tasks_max_scale(UINT32_MAX, UINT32_MAX) == t); /* overflow */ assert_se(system_tasks_max_scale(UINT64_MAX/4, UINT64_MAX) == UINT64_MAX); } int main(int argc, char *argv[]) { log_parse_environment(); log_open(); test_align_power2(); test_max(); test_container_of(); test_div_round_up(); test_u64log2(); test_protect_errno(); test_in_set(); test_log2i(); test_raw_clone(); test_physical_memory(); test_physical_memory_scale(); test_system_tasks_max(); test_system_tasks_max_scale(); return 0; }