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1022 1023 1024 1025 1026 1027 1028 1029 1030 1031 1032 1033 1034 1035 1036 1037 1038 1039 1040 1041 1042 1043 1044 1045 1046 1047 1048 1049 1050 1051 1052 1053 1054 1055 1056 1057 1058 1059 1060 1061 1062 1063 1064 1065 1066 1067 1068 1069 1070 1071 1072 1073 1074 1075 1076 1077 1078 1079 1080 1081 1082 1083 1084 1085 1086 1087 1088 1089 1090 1091 1092 1093 1094 1095 1096 1097 1098 1099 1100 1101 1102 1103 1104 1105 1106 1107 1108 1109 1110 1111 1112 1113 1114 1115 1116 1117 1118 1119 1120 1121 1122 1123 | #ifdef T_NAMESPACE #undef T_NAMESPACE #endif #include <darwintest.h> #include <unistd.h> #include <signal.h> #include <sys/time.h> #include <sys/mman.h> #include <immintrin.h> #include <mach/mach.h> #include <stdio.h> #include <string.h> #include <err.h> #include <i386/cpu_capabilities.h> T_GLOBAL_META( T_META_NAMESPACE("xnu.intel"), T_META_CHECK_LEAKS(false), T_META_RADAR_COMPONENT_NAME("xnu"), T_META_RADAR_COMPONENT_VERSION("intel"), T_META_OWNER("seth_goldberg"), T_META_RUN_CONCURRENTLY(true) ); #define QUICK_RUN_TIME (2) #define NORMAL_RUN_TIME (10) #define LONG_RUN_TIME (10*60) #define TIMEOUT_OVERHEAD (10) volatile boolean_t checking = true; char vec_str_buf[8196]; char karray_str_buf[1024]; /* * ymm defines/globals/prototypes */ #define STOP_COOKIE_256 0x01234567 #if defined(__x86_64__) #define YMM_MAX 16 #define X86_AVX_STATE_T x86_avx_state64_t #define X86_AVX_STATE_COUNT x86_AVX_STATE64_COUNT #define X86_AVX_STATE_FLAVOR x86_AVX_STATE64 #define MCONTEXT_SIZE_256 sizeof(struct __darwin_mcontext_avx64) #else #define YMM_MAX 8 #define X86_AVX_STATE_T x86_avx_state32_t #define X86_AVX_STATE_COUNT x86_AVX_STATE32_COUNT #define X86_AVX_STATE_FLAVOR x86_AVX_STATE32 #define MCONTEXT_SIZE_256 sizeof(struct __darwin_mcontext_avx32) #endif #define VECTOR256 __m256 #define VEC256ALIGN __attribute ((aligned(32))) static inline void populate_ymm(void); static inline void check_ymm(void); VECTOR256 vec256array0[YMM_MAX] VEC256ALIGN; VECTOR256 vec256array1[YMM_MAX] VEC256ALIGN; VECTOR256 vec256array2[YMM_MAX] VEC256ALIGN; VECTOR256 vec256array3[YMM_MAX] VEC256ALIGN; /* * zmm defines/globals/prototypes */ #define STOP_COOKIE_512 0x0123456789abcdefULL #if defined(__x86_64__) #define ZMM_MAX 32 #define X86_AVX512_STATE_T x86_avx512_state64_t #define X86_AVX512_STATE_COUNT x86_AVX512_STATE64_COUNT #define X86_AVX512_STATE_FLAVOR x86_AVX512_STATE64 #define MCONTEXT_SIZE_512 sizeof(struct __darwin_mcontext_avx512_64) #else #define ZMM_MAX 8 #define X86_AVX512_STATE_T x86_avx512_state32_t #define X86_AVX512_STATE_COUNT x86_AVX512_STATE32_COUNT #define X86_AVX512_STATE_FLAVOR x86_AVX512_STATE32 #define MCONTEXT_SIZE_512 sizeof(struct __darwin_mcontext_avx512_32) #endif #define VECTOR512 __m512 #define VEC512ALIGN __attribute ((aligned(64))) #define OPMASK uint64_t #define KARRAY_MAX 8 static inline void zero_zmm(void); static inline void zero_opmask(void); static inline void populate_zmm(void); static inline void populate_opmask(void); static inline void check_zmm(boolean_t check_cookie); VECTOR512 vec512array0[ZMM_MAX] VEC512ALIGN; VECTOR512 vec512array1[ZMM_MAX] VEC512ALIGN; VECTOR512 vec512array2[ZMM_MAX] VEC512ALIGN; VECTOR512 vec512array3[ZMM_MAX] VEC512ALIGN; OPMASK karray0[8]; OPMASK karray1[8]; OPMASK karray2[8]; OPMASK karray3[8]; kern_return_t _thread_get_state_avx(thread_t thread, int flavor, thread_state_t state, mach_msg_type_number_t *state_count); kern_return_t _thread_get_state_avx512(thread_t thread, int flavor, thread_state_t state, mach_msg_type_number_t *state_count); /* * Common functions */ int memcmp_unoptimized(const void *s1, const void *s2, size_t n) { if (n != 0) { const unsigned char *p1 = s1, *p2 = s2; do { if (*p1++ != *p2++) { return *--p1 - *--p2; } } while (--n != 0); } return 0; } void start_timer(int seconds, void (*handler)(int, siginfo_t *, void *)) { struct sigaction sigalrm_action = { .sa_sigaction = handler, .sa_flags = SA_RESTART, .sa_mask = 0 }; struct itimerval timer = { .it_value.tv_sec = seconds, .it_value.tv_usec = 0, .it_interval.tv_sec = 0, .it_interval.tv_usec = 0 }; T_QUIET; T_WITH_ERRNO; T_ASSERT_NE(sigaction(SIGALRM, &sigalrm_action, NULL), -1, NULL); T_QUIET; T_WITH_ERRNO; T_ASSERT_NE(setitimer(ITIMER_REAL, &timer, NULL), -1, NULL); } void require_avx(void) { if ((_get_cpu_capabilities() & kHasAVX1_0) != kHasAVX1_0) { T_SKIP("AVX not supported on this system"); } } void require_avx512(void) { if ((_get_cpu_capabilities() & kHasAVX512F) != kHasAVX512F) { T_SKIP("AVX-512 not supported on this system"); } } /* * ymm functions */ static inline void store_ymm(VECTOR256 *vec256array) { int i = 0; __asm__ volatile ("vmovaps %%ymm0, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm1, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm2, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm3, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm4, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm5, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm6, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm7, %0" :"=m" (vec256array[i])); #if defined(__x86_64__) i++; __asm__ volatile ("vmovaps %%ymm8, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm9, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm10, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm11, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm12, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm13, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm14, %0" :"=m" (vec256array[i])); i++; __asm__ volatile ("vmovaps %%ymm15, %0" :"=m" (vec256array[i])); #endif } static inline void restore_ymm(VECTOR256 *vec256array) { VECTOR256 *p = vec256array; __asm__ volatile ("vmovaps %0, %%ymm0" :: "m" (*(__m256i*)p) : "ymm0"); p++; __asm__ volatile ("vmovaps %0, %%ymm1" :: "m" (*(__m256i*)p) : "ymm1"); p++; __asm__ volatile ("vmovaps %0, %%ymm2" :: "m" (*(__m256i*)p) : "ymm2"); p++; __asm__ volatile ("vmovaps %0, %%ymm3" :: "m" (*(__m256i*)p) : "ymm3"); p++; __asm__ volatile ("vmovaps %0, %%ymm4" :: "m" (*(__m256i*)p) : "ymm4"); p++; __asm__ volatile ("vmovaps %0, %%ymm5" :: "m" (*(__m256i*)p) : "ymm5"); p++; __asm__ volatile ("vmovaps %0, %%ymm6" :: "m" (*(__m256i*)p) : "ymm6"); p++; __asm__ volatile ("vmovaps %0, %%ymm7" :: "m" (*(__m256i*)p) : "ymm7"); #if defined(__x86_64__) ++p; __asm__ volatile ("vmovaps %0, %%ymm8" :: "m" (*(__m256i*)p) : "ymm8"); p++; __asm__ volatile ("vmovaps %0, %%ymm9" :: "m" (*(__m256i*)p) : "ymm9"); p++; __asm__ volatile ("vmovaps %0, %%ymm10" :: "m" (*(__m256i*)p) : "ymm10"); p++; __asm__ volatile ("vmovaps %0, %%ymm11" :: "m" (*(__m256i*)p) : "ymm11"); p++; __asm__ volatile ("vmovaps %0, %%ymm12" :: "m" (*(__m256i*)p) : "ymm12"); p++; __asm__ volatile ("vmovaps %0, %%ymm13" :: "m" (*(__m256i*)p) : "ymm13"); p++; __asm__ volatile ("vmovaps %0, %%ymm14" :: "m" (*(__m256i*)p) : "ymm14"); p++; __asm__ volatile ("vmovaps %0, %%ymm15" :: "m" (*(__m256i*)p) : "ymm15"); #endif } static inline void populate_ymm(void) { int j; uint32_t p[8] VEC256ALIGN; for (j = 0; j < (int) (sizeof(p) / sizeof(p[0])); j++) { p[j] = getpid(); } p[0] = 0x22222222; p[7] = 0x77777777; __asm__ volatile ("vmovaps %0, %%ymm0" :: "m" (*(__m256i*)p) : "ymm0"); __asm__ volatile ("vmovaps %0, %%ymm1" :: "m" (*(__m256i*)p) : "ymm1"); __asm__ volatile ("vmovaps %0, %%ymm2" :: "m" (*(__m256i*)p) : "ymm2"); __asm__ volatile ("vmovaps %0, %%ymm3" :: "m" (*(__m256i*)p) : "ymm3"); p[0] = 0x44444444; p[7] = 0xEEEEEEEE; __asm__ volatile ("vmovaps %0, %%ymm4" :: "m" (*(__m256i*)p) : "ymm4"); __asm__ volatile ("vmovaps %0, %%ymm5" :: "m" (*(__m256i*)p) : "ymm5"); __asm__ volatile ("vmovaps %0, %%ymm6" :: "m" (*(__m256i*)p) : "ymm6"); __asm__ volatile ("vmovaps %0, %%ymm7" :: "m" (*(__m256i*)p) : "ymm7"); #if defined(__x86_64__) p[0] = 0x88888888; p[7] = 0xAAAAAAAA; __asm__ volatile ("vmovaps %0, %%ymm8" :: "m" (*(__m256i*)p) : "ymm8"); __asm__ volatile ("vmovaps %0, %%ymm9" :: "m" (*(__m256i*)p) : "ymm9"); __asm__ volatile ("vmovaps %0, %%ymm10" :: "m" (*(__m256i*)p) : "ymm10"); __asm__ volatile ("vmovaps %0, %%ymm11" :: "m" (*(__m256i*)p) : "ymm11"); p[0] = 0xBBBBBBBB; p[7] = 0xCCCCCCCC; __asm__ volatile ("vmovaps %0, %%ymm12" :: "m" (*(__m256i*)p) : "ymm12"); __asm__ volatile ("vmovaps %0, %%ymm13" :: "m" (*(__m256i*)p) : "ymm13"); __asm__ volatile ("vmovaps %0, %%ymm14" :: "m" (*(__m256i*)p) : "ymm14"); __asm__ volatile ("vmovaps %0, %%ymm15" :: "m" (*(__m256i*)p) : "ymm15"); #endif store_ymm(vec256array0); } void vec256_to_string(VECTOR256 *vec, char *buf) { unsigned int vec_idx = 0; unsigned int buf_idx = 0; int ret = 0; for (vec_idx = 0; vec_idx < YMM_MAX; vec_idx++) { uint64_t a[4]; bcopy(&vec[vec_idx], &a[0], sizeof(a)); ret = sprintf( buf + buf_idx, "0x%016llx:%016llx:%016llx:%016llx\n", a[0], a[1], a[2], a[3] ); T_QUIET; T_ASSERT_POSIX_SUCCESS(ret, "sprintf()"); buf_idx += ret; } } void assert_ymm_eq(void *a, void *b, int c) { if (memcmp_unoptimized(a, b, c)) { vec256_to_string(a, vec_str_buf); T_LOG("Compare failed, vector A:\n%s", vec_str_buf); vec256_to_string(b, vec_str_buf); T_LOG("Compare failed, vector B:\n%s", vec_str_buf); T_ASSERT_FAIL("vectors not equal"); } } void check_ymm(void) { uint32_t *p = (uint32_t *) &vec256array1[7]; store_ymm(vec256array1); if (p[0] == STOP_COOKIE_256) { return; } assert_ymm_eq(vec256array0, vec256array1, sizeof(vec256array0)); } static void copy_ymm_state_to_vector(X86_AVX_STATE_T *sp, VECTOR256 *vp) { int i; struct __darwin_xmm_reg *xmm = &sp->__fpu_xmm0; struct __darwin_xmm_reg *ymmh = &sp->__fpu_ymmh0; for (i = 0; i < YMM_MAX; i++) { bcopy(&xmm[i], &vp[i], sizeof(*xmm)); bcopy(&ymmh[i], (void *) ((uint64_t)&vp[i] + sizeof(*ymmh)), sizeof(*ymmh)); } } static void ymm_sigalrm_handler(int signum __unused, siginfo_t *info __unused, void *ctx) { ucontext_t *contextp = (ucontext_t *) ctx; mcontext_t mcontext = contextp->uc_mcontext; X86_AVX_STATE_T *avx_state = (X86_AVX_STATE_T *) &mcontext->__fs; uint32_t *xp = (uint32_t *) &avx_state->__fpu_xmm7; uint32_t *yp = (uint32_t *) &avx_state->__fpu_ymmh7; T_LOG("Got SIGALRM"); /* Check for AVX state */ T_QUIET; T_ASSERT_GE(contextp->uc_mcsize, MCONTEXT_SIZE_256, "check context size"); /* Check that the state in the context is what's set and expected */ copy_ymm_state_to_vector(avx_state, vec256array3); assert_ymm_eq(vec256array3, vec256array0, sizeof(vec256array1)); /* Change the context and break the main loop */ xp[0] = STOP_COOKIE_256; yp[0] = STOP_COOKIE_256; checking = FALSE; } kern_return_t _thread_get_state_avx( thread_t thread, int flavor, thread_state_t state, /* pointer to OUT array */ mach_msg_type_number_t *state_count) /*IN/OUT*/ { kern_return_t rv; VECTOR256 ymms[YMM_MAX]; /* * We must save and restore the YMMs across thread_get_state() because * code in thread_get_state changes at least one xmm register AFTER the * thread_get_state has saved the state in userspace. While it's still * possible for something to muck with %xmms BEFORE making the mach * system call (and rendering this save/restore useless), that does not * currently occur, and since we depend on the avx state saved in the * thread_get_state to be the same as that manually copied from YMMs after * thread_get_state returns, we have to go through these machinations. */ store_ymm(ymms); rv = thread_get_state(thread, flavor, state, state_count); restore_ymm(ymms); return rv; } void ymm_integrity(int time) { mach_msg_type_number_t avx_count = X86_AVX_STATE_COUNT; kern_return_t kret; X86_AVX_STATE_T avx_state, avx_state2; mach_port_t ts = mach_thread_self(); bzero(&avx_state, sizeof(avx_state)); bzero(&avx_state2, sizeof(avx_state)); kret = _thread_get_state_avx( ts, X86_AVX_STATE_FLAVOR, (thread_state_t)&avx_state, &avx_count ); store_ymm(vec256array2); T_QUIET; T_ASSERT_MACH_SUCCESS(kret, "thread_get_state()"); vec256_to_string(vec256array2, vec_str_buf); T_LOG("Initial state:\n%s", vec_str_buf); copy_ymm_state_to_vector(&avx_state, vec256array1); assert_ymm_eq(vec256array2, vec256array1, sizeof(vec256array1)); populate_ymm(); kret = _thread_get_state_avx( ts, X86_AVX_STATE_FLAVOR, (thread_state_t)&avx_state2, &avx_count ); store_ymm(vec256array2); T_QUIET; T_ASSERT_MACH_SUCCESS(kret, "thread_get_state()"); vec256_to_string(vec256array2, vec_str_buf); T_LOG("Populated state:\n%s", vec_str_buf); copy_ymm_state_to_vector(&avx_state2, vec256array1); assert_ymm_eq(vec256array2, vec256array1, sizeof(vec256array0)); T_LOG("Running for %ds…", time); start_timer(time, ymm_sigalrm_handler); /* re-populate because printing mucks up XMMs */ populate_ymm(); /* Check state until timer fires */ while (checking) { check_ymm(); } /* Check that the sig handler changed out AVX state */ store_ymm(vec256array1); uint32_t *p = (uint32_t *) &vec256array1[7]; if (p[0] != STOP_COOKIE_256 || p[4] != STOP_COOKIE_256) { vec256_to_string(vec256array1, vec_str_buf); T_ASSERT_FAIL("sigreturn failed to stick"); T_LOG("State:\n%s", vec_str_buf); } T_LOG("Ran for %ds", time); T_PASS("No ymm register corruption occurred"); } /* * zmm functions */ static inline void store_opmask(OPMASK k[]) { __asm__ volatile ("kmovq %%k0, %0" :"=m" (k[0])); __asm__ volatile ("kmovq %%k1, %0" :"=m" (k[1])); __asm__ volatile ("kmovq %%k2, %0" :"=m" (k[2])); __asm__ volatile ("kmovq %%k3, %0" :"=m" (k[3])); __asm__ volatile ("kmovq %%k4, %0" :"=m" (k[4])); __asm__ volatile ("kmovq %%k5, %0" :"=m" (k[5])); __asm__ volatile ("kmovq %%k6, %0" :"=m" (k[6])); __asm__ volatile ("kmovq %%k7, %0" :"=m" (k[7])); } static inline void store_zmm(VECTOR512 *vecarray) { int i = 0; __asm__ volatile ("vmovaps %%zmm0, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm1, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm2, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm3, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm4, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm5, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm6, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm7, %0" :"=m" (vecarray[i])); #if defined(__x86_64__) i++; __asm__ volatile ("vmovaps %%zmm8, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm9, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm10, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm11, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm12, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm13, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm14, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm15, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm16, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm17, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm18, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm19, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm20, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm21, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm22, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm23, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm24, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm25, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm26, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm27, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm28, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm29, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm30, %0" :"=m" (vecarray[i])); i++; __asm__ volatile ("vmovaps %%zmm31, %0" :"=m" (vecarray[i])); #endif } static inline void restore_zmm(VECTOR512 *vecarray) { VECTOR512 *p = vecarray; __asm__ volatile ("vmovaps %0, %%zmm0" :: "m" (*(__m512i*)p) : "zmm0"); p++; __asm__ volatile ("vmovaps %0, %%zmm1" :: "m" (*(__m512i*)p) : "zmm1"); p++; __asm__ volatile ("vmovaps %0, %%zmm2" :: "m" (*(__m512i*)p) : "zmm2"); p++; __asm__ volatile ("vmovaps %0, %%zmm3" :: "m" (*(__m512i*)p) : "zmm3"); p++; __asm__ volatile ("vmovaps %0, %%zmm4" :: "m" (*(__m512i*)p) : "zmm4"); p++; __asm__ volatile ("vmovaps %0, %%zmm5" :: "m" (*(__m512i*)p) : "zmm5"); p++; __asm__ volatile ("vmovaps %0, %%zmm6" :: "m" (*(__m512i*)p) : "zmm6"); p++; __asm__ volatile ("vmovaps %0, %%zmm7" :: "m" (*(__m512i*)p) : "zmm7"); #if defined(__x86_64__) ++p; __asm__ volatile ("vmovaps %0, %%zmm8" :: "m" (*(__m512i*)p) : "zmm8"); p++; __asm__ volatile ("vmovaps %0, %%zmm9" :: "m" (*(__m512i*)p) : "zmm9"); p++; __asm__ volatile ("vmovaps %0, %%zmm10" :: "m" (*(__m512i*)p) : "zmm10"); p++; __asm__ volatile ("vmovaps %0, %%zmm11" :: "m" (*(__m512i*)p) : "zmm11"); p++; __asm__ volatile ("vmovaps %0, %%zmm12" :: "m" (*(__m512i*)p) : "zmm12"); p++; __asm__ volatile ("vmovaps %0, %%zmm13" :: "m" (*(__m512i*)p) : "zmm13"); p++; __asm__ volatile ("vmovaps %0, %%zmm14" :: "m" (*(__m512i*)p) : "zmm14"); p++; __asm__ volatile ("vmovaps %0, %%zmm15" :: "m" (*(__m512i*)p) : "zmm15"); p++; __asm__ volatile ("vmovaps %0, %%zmm16" :: "m" (*(__m512i*)p) : "zmm16"); p++; __asm__ volatile ("vmovaps %0, %%zmm17" :: "m" (*(__m512i*)p) : "zmm17"); p++; __asm__ volatile ("vmovaps %0, %%zmm18" :: "m" (*(__m512i*)p) : "zmm18"); p++; __asm__ volatile ("vmovaps %0, %%zmm19" :: "m" (*(__m512i*)p) : "zmm19"); p++; __asm__ volatile ("vmovaps %0, %%zmm20" :: "m" (*(__m512i*)p) : "zmm20"); p++; __asm__ volatile ("vmovaps %0, %%zmm21" :: "m" (*(__m512i*)p) : "zmm21"); p++; __asm__ volatile ("vmovaps %0, %%zmm22" :: "m" (*(__m512i*)p) : "zmm22"); p++; __asm__ volatile ("vmovaps %0, %%zmm23" :: "m" (*(__m512i*)p) : "zmm23"); p++; __asm__ volatile ("vmovaps %0, %%zmm24" :: "m" (*(__m512i*)p) : "zmm24"); p++; __asm__ volatile ("vmovaps %0, %%zmm25" :: "m" (*(__m512i*)p) : "zmm25"); p++; __asm__ volatile ("vmovaps %0, %%zmm26" :: "m" (*(__m512i*)p) : "zmm26"); p++; __asm__ volatile ("vmovaps %0, %%zmm27" :: "m" (*(__m512i*)p) : "zmm27"); p++; __asm__ volatile ("vmovaps %0, %%zmm28" :: "m" (*(__m512i*)p) : "zmm28"); p++; __asm__ volatile ("vmovaps %0, %%zmm29" :: "m" (*(__m512i*)p) : "zmm29"); p++; __asm__ volatile ("vmovaps %0, %%zmm30" :: "m" (*(__m512i*)p) : "zmm30"); p++; __asm__ volatile ("vmovaps %0, %%zmm31" :: "m" (*(__m512i*)p) : "zmm31"); #endif } static inline void zero_opmask(void) { uint64_t zero = 0x0000000000000000ULL; __asm__ volatile ("kmovq %0, %%k0" : :"m" (zero) : "k0"); __asm__ volatile ("kmovq %0, %%k1" : :"m" (zero) : "k1"); __asm__ volatile ("kmovq %0, %%k2" : :"m" (zero) : "k2"); __asm__ volatile ("kmovq %0, %%k3" : :"m" (zero) : "k3"); __asm__ volatile ("kmovq %0, %%k4" : :"m" (zero) : "k4"); __asm__ volatile ("kmovq %0, %%k5" : :"m" (zero) : "k5"); __asm__ volatile ("kmovq %0, %%k6" : :"m" (zero) : "k6"); __asm__ volatile ("kmovq %0, %%k7" : :"m" (zero) : "k7"); store_opmask(karray0); } static inline void populate_opmask(void) { uint64_t k[8]; for (int j = 0; j < 8; j++) { k[j] = ((uint64_t) getpid() << 32) + (0x11111111 * j); } __asm__ volatile ("kmovq %0, %%k0" : :"m" (k[0]) : "k0"); __asm__ volatile ("kmovq %0, %%k1" : :"m" (k[1]) : "k1"); __asm__ volatile ("kmovq %0, %%k2" : :"m" (k[2]) : "k2"); __asm__ volatile ("kmovq %0, %%k3" : :"m" (k[3]) : "k3"); __asm__ volatile ("kmovq %0, %%k4" : :"m" (k[4]) : "k4"); __asm__ volatile ("kmovq %0, %%k5" : :"m" (k[5]) : "k5"); __asm__ volatile ("kmovq %0, %%k6" : :"m" (k[6]) : "k6"); __asm__ volatile ("kmovq %0, %%k7" : :"m" (k[7]) : "k7"); store_opmask(karray0); } kern_return_t _thread_get_state_avx512( thread_t thread, int flavor, thread_state_t state, /* pointer to OUT array */ mach_msg_type_number_t *state_count) /*IN/OUT*/ { kern_return_t rv; VECTOR512 zmms[ZMM_MAX]; /* * We must save and restore the ZMMs across thread_get_state() because * code in thread_get_state changes at least one xmm register AFTER the * thread_get_state has saved the state in userspace. While it's still * possible for something to muck with %XMMs BEFORE making the mach * system call (and rendering this save/restore useless), that does not * currently occur, and since we depend on the avx512 state saved in the * thread_get_state to be the same as that manually copied from ZMMs after * thread_get_state returns, we have to go through these machinations. */ store_zmm(zmms); rv = thread_get_state(thread, flavor, state, state_count); restore_zmm(zmms); return rv; } static inline void zero_zmm(void) { uint64_t zero[8] VEC512ALIGN = {0}; __asm__ volatile ("vmovaps %0, %%zmm0" :: "m" (zero) : "zmm0"); __asm__ volatile ("vmovaps %0, %%zmm1" :: "m" (zero) : "zmm1"); __asm__ volatile ("vmovaps %0, %%zmm2" :: "m" (zero) : "zmm2"); __asm__ volatile ("vmovaps %0, %%zmm3" :: "m" (zero) : "zmm3"); __asm__ volatile ("vmovaps %0, %%zmm4" :: "m" (zero) : "zmm4"); __asm__ volatile ("vmovaps %0, %%zmm5" :: "m" (zero) : "zmm5"); __asm__ volatile ("vmovaps %0, %%zmm6" :: "m" (zero) : "zmm6"); __asm__ volatile ("vmovaps %0, %%zmm7" :: "m" (zero) : "zmm7"); #if defined(__x86_64__) __asm__ volatile ("vmovaps %0, %%zmm8" :: "m" (zero) : "zmm8"); __asm__ volatile ("vmovaps %0, %%zmm9" :: "m" (zero) : "zmm9"); __asm__ volatile ("vmovaps %0, %%zmm10" :: "m" (zero) : "zmm10"); __asm__ volatile ("vmovaps %0, %%zmm11" :: "m" (zero) : "zmm11"); __asm__ volatile ("vmovaps %0, %%zmm12" :: "m" (zero) : "zmm12"); __asm__ volatile ("vmovaps %0, %%zmm13" :: "m" (zero) : "zmm13"); __asm__ volatile ("vmovaps %0, %%zmm14" :: "m" (zero) : "zmm14"); __asm__ volatile ("vmovaps %0, %%zmm15" :: "m" (zero) : "zmm15"); __asm__ volatile ("vmovaps %0, %%zmm16" :: "m" (zero) : "zmm16"); __asm__ volatile ("vmovaps %0, %%zmm17" :: "m" (zero) : "zmm17"); __asm__ volatile ("vmovaps %0, %%zmm18" :: "m" (zero) : "zmm18"); __asm__ volatile ("vmovaps %0, %%zmm19" :: "m" (zero) : "zmm19"); __asm__ volatile ("vmovaps %0, %%zmm20" :: "m" (zero) : "zmm20"); __asm__ volatile ("vmovaps %0, %%zmm21" :: "m" (zero) : "zmm21"); __asm__ volatile ("vmovaps %0, %%zmm22" :: "m" (zero) : "zmm22"); __asm__ volatile ("vmovaps %0, %%zmm23" :: "m" (zero) : "zmm23"); __asm__ volatile ("vmovaps %0, %%zmm24" :: "m" (zero) : "zmm24"); __asm__ volatile ("vmovaps %0, %%zmm25" :: "m" (zero) : "zmm25"); __asm__ volatile ("vmovaps %0, %%zmm26" :: "m" (zero) : "zmm26"); __asm__ volatile ("vmovaps %0, %%zmm27" :: "m" (zero) : "zmm27"); __asm__ volatile ("vmovaps %0, %%zmm28" :: "m" (zero) : "zmm28"); __asm__ volatile ("vmovaps %0, %%zmm29" :: "m" (zero) : "zmm29"); __asm__ volatile ("vmovaps %0, %%zmm30" :: "m" (zero) : "zmm30"); __asm__ volatile ("vmovaps %0, %%zmm31" :: "m" (zero) : "zmm31"); #endif store_zmm(vec512array0); } static inline void populate_zmm(void) { int j; uint64_t p[8] VEC512ALIGN; for (j = 0; j < (int) (sizeof(p) / sizeof(p[0])); j++) { p[j] = ((uint64_t) getpid() << 32) + getpid(); } p[0] = 0x0000000000000000ULL; p[2] = 0x4444444444444444ULL; p[4] = 0x8888888888888888ULL; p[7] = 0xCCCCCCCCCCCCCCCCULL; __asm__ volatile ("vmovaps %0, %%zmm0" :: "m" (*(__m512i*)p) : "zmm0"); __asm__ volatile ("vmovaps %0, %%zmm1" :: "m" (*(__m512i*)p) : "zmm1"); __asm__ volatile ("vmovaps %0, %%zmm2" :: "m" (*(__m512i*)p) : "zmm2"); __asm__ volatile ("vmovaps %0, %%zmm3" :: "m" (*(__m512i*)p) : "zmm3"); __asm__ volatile ("vmovaps %0, %%zmm4" :: "m" (*(__m512i*)p) : "zmm4"); __asm__ volatile ("vmovaps %0, %%zmm5" :: "m" (*(__m512i*)p) : "zmm5"); __asm__ volatile ("vmovaps %0, %%zmm6" :: "m" (*(__m512i*)p) : "zmm6"); __asm__ volatile ("vmovaps %0, %%zmm7" :: "m" (*(__m512i*)p) : "zmm7"); #if defined(__x86_64__) p[0] = 0x1111111111111111ULL; p[2] = 0x5555555555555555ULL; p[4] = 0x9999999999999999ULL; p[7] = 0xDDDDDDDDDDDDDDDDULL; __asm__ volatile ("vmovaps %0, %%zmm8" :: "m" (*(__m512i*)p) : "zmm8"); __asm__ volatile ("vmovaps %0, %%zmm9" :: "m" (*(__m512i*)p) : "zmm9"); __asm__ volatile ("vmovaps %0, %%zmm10" :: "m" (*(__m512i*)p) : "zmm10"); __asm__ volatile ("vmovaps %0, %%zmm11" :: "m" (*(__m512i*)p) : "zmm11"); __asm__ volatile ("vmovaps %0, %%zmm12" :: "m" (*(__m512i*)p) : "zmm12"); __asm__ volatile ("vmovaps %0, %%zmm13" :: "m" (*(__m512i*)p) : "zmm13"); __asm__ volatile ("vmovaps %0, %%zmm14" :: "m" (*(__m512i*)p) : "zmm14"); __asm__ volatile ("vmovaps %0, %%zmm15" :: "m" (*(__m512i*)p) : "zmm15"); p[0] = 0x2222222222222222ULL; p[2] = 0x6666666666666666ULL; p[4] = 0xAAAAAAAAAAAAAAAAULL; p[7] = 0xEEEEEEEEEEEEEEEEULL; __asm__ volatile ("vmovaps %0, %%zmm16" :: "m" (*(__m512i*)p) : "zmm16"); __asm__ volatile ("vmovaps %0, %%zmm17" :: "m" (*(__m512i*)p) : "zmm17"); __asm__ volatile ("vmovaps %0, %%zmm18" :: "m" (*(__m512i*)p) : "zmm18"); __asm__ volatile ("vmovaps %0, %%zmm19" :: "m" (*(__m512i*)p) : "zmm19"); __asm__ volatile ("vmovaps %0, %%zmm20" :: "m" (*(__m512i*)p) : "zmm20"); __asm__ volatile ("vmovaps %0, %%zmm21" :: "m" (*(__m512i*)p) : "zmm21"); __asm__ volatile ("vmovaps %0, %%zmm22" :: "m" (*(__m512i*)p) : "zmm22"); __asm__ volatile ("vmovaps %0, %%zmm23" :: "m" (*(__m512i*)p) : "zmm23"); p[0] = 0x3333333333333333ULL; p[2] = 0x7777777777777777ULL; p[4] = 0xBBBBBBBBBBBBBBBBULL; p[7] = 0xFFFFFFFFFFFFFFFFULL; __asm__ volatile ("vmovaps %0, %%zmm24" :: "m" (*(__m512i*)p) : "zmm24"); __asm__ volatile ("vmovaps %0, %%zmm25" :: "m" (*(__m512i*)p) : "zmm25"); __asm__ volatile ("vmovaps %0, %%zmm26" :: "m" (*(__m512i*)p) : "zmm26"); __asm__ volatile ("vmovaps %0, %%zmm27" :: "m" (*(__m512i*)p) : "zmm27"); __asm__ volatile ("vmovaps %0, %%zmm28" :: "m" (*(__m512i*)p) : "zmm28"); __asm__ volatile ("vmovaps %0, %%zmm29" :: "m" (*(__m512i*)p) : "zmm29"); __asm__ volatile ("vmovaps %0, %%zmm30" :: "m" (*(__m512i*)p) : "zmm30"); __asm__ volatile ("vmovaps %0, %%zmm31" :: "m" (*(__m512i*)p) : "zmm31"); #endif store_zmm(vec512array0); } void vec512_to_string(VECTOR512 *vec, char *buf) { unsigned int vec_idx = 0; unsigned int buf_idx = 0; int ret = 0; for (vec_idx = 0; vec_idx < ZMM_MAX; vec_idx++) { uint64_t a[8]; bcopy(&vec[vec_idx], &a[0], sizeof(a)); ret = sprintf( buf + buf_idx, "0x%016llx:%016llx:%016llx:%016llx:" "%016llx:%016llx:%016llx:%016llx%s", a[0], a[1], a[2], a[3], a[4], a[5], a[6], a[7], vec_idx < ZMM_MAX - 1 ? "\n" : "" ); T_QUIET; T_ASSERT_POSIX_SUCCESS(ret, "sprintf()"); buf_idx += ret; } } void opmask_to_string(OPMASK *karray, char *buf) { unsigned int karray_idx = 0; unsigned int buf_idx = 0; int ret = 0; for (karray_idx = 0; karray_idx < KARRAY_MAX; karray_idx++) { ret = sprintf( buf + buf_idx, "k%d: 0x%016llx%s", karray_idx, karray[karray_idx], karray_idx < KARRAY_MAX ? "\n" : "" ); T_QUIET; T_ASSERT_POSIX_SUCCESS(ret, "sprintf()"); buf_idx += ret; } } static void assert_zmm_eq(void *a, void *b, int c) { if (memcmp_unoptimized(a, b, c)) { vec512_to_string(a, vec_str_buf); T_LOG("Compare failed, vector A:\n%s", vec_str_buf); vec512_to_string(b, vec_str_buf); T_LOG("Compare failed, vector B:\n%s", vec_str_buf); T_ASSERT_FAIL("Vectors not equal"); } } static void assert_opmask_eq(OPMASK *a, OPMASK *b) { for (int i = 0; i < KARRAY_MAX; i++) { if (a[i] != b[i]) { opmask_to_string(a, karray_str_buf); T_LOG("Compare failed, opmask A:\n%s", karray_str_buf); opmask_to_string(b, karray_str_buf); T_LOG("Compare failed, opmask B:\n%s", karray_str_buf); T_ASSERT_FAIL("opmasks not equal"); } } } void check_zmm(boolean_t check_cookie) { uint64_t *p = (uint64_t *) &vec512array1[7]; store_opmask(karray1); store_zmm(vec512array1); if (check_cookie && p[0] == STOP_COOKIE_512) { return; } assert_zmm_eq(vec512array0, vec512array1, sizeof(vec512array0)); assert_opmask_eq(karray0, karray1); } static void copy_state_to_opmask(X86_AVX512_STATE_T *sp, OPMASK *op) { OPMASK *k = (OPMASK *) &sp->__fpu_k0; for (int i = 0; i < KARRAY_MAX; i++) { bcopy(&k[i], &op[i], sizeof(*op)); } } static void copy_zmm_state_to_vector(X86_AVX512_STATE_T *sp, VECTOR512 *vp) { int i; struct __darwin_xmm_reg *xmm = &sp->__fpu_xmm0; struct __darwin_xmm_reg *ymmh = &sp->__fpu_ymmh0; struct __darwin_ymm_reg *zmmh = &sp->__fpu_zmmh0; #if defined(__x86_64__) struct __darwin_zmm_reg *zmm = &sp->__fpu_zmm16; for (i = 0; i < ZMM_MAX / 2; i++) { bcopy(&xmm[i], &vp[i], sizeof(*xmm)); bcopy(&ymmh[i], (void *) ((uint64_t)&vp[i] + sizeof(*ymmh)), sizeof(*ymmh)); bcopy(&zmmh[i], (void *) ((uint64_t)&vp[i] + sizeof(*zmmh)), sizeof(*zmmh)); bcopy(&zmm[i], &vp[(ZMM_MAX / 2) + i], sizeof(*zmm)); } #else for (i = 0; i < ZMM_MAX; i++) { bcopy(&xmm[i], &vp[i], sizeof(*xmm)); bcopy(&ymmh[i], (void *) ((uint64_t)&vp[i] + sizeof(*ymmh)), sizeof(*ymmh)); bcopy(&zmmh[i], (void *) ((uint64_t)&vp[i] + sizeof(*zmmh)), sizeof(*zmmh)); } #endif } static void zmm_sigalrm_handler(int signum __unused, siginfo_t *info __unused, void *ctx) { ucontext_t *contextp = (ucontext_t *) ctx; mcontext_t mcontext = contextp->uc_mcontext; X86_AVX512_STATE_T *avx_state = (X86_AVX512_STATE_T *) &mcontext->__fs; uint64_t *xp = (uint64_t *) &avx_state->__fpu_xmm7; uint64_t *yp = (uint64_t *) &avx_state->__fpu_ymmh7; uint64_t *zp = (uint64_t *) &avx_state->__fpu_zmmh7; uint64_t *kp = (uint64_t *) &avx_state->__fpu_k0; /* Check for AVX512 state */ T_QUIET; T_ASSERT_GE(contextp->uc_mcsize, MCONTEXT_SIZE_512, "check context size"); /* Check that the state in the context is what's set and expected */ copy_zmm_state_to_vector(avx_state, vec512array3); assert_zmm_eq(vec512array3, vec512array0, sizeof(vec512array3)); copy_state_to_opmask(avx_state, karray3); assert_opmask_eq(karray3, karray0); /* Change the context and break the main loop */ xp[0] = STOP_COOKIE_512; yp[0] = STOP_COOKIE_512; zp[0] = STOP_COOKIE_512; kp[7] = STOP_COOKIE_512; checking = FALSE; } static void zmm_sigalrm_handler_no_mod(int signum __unused, siginfo_t *info __unused, void *ctx) { ucontext_t *contextp = (ucontext_t *) ctx; mcontext_t mcontext = contextp->uc_mcontext; X86_AVX512_STATE_T *avx_state = (X86_AVX512_STATE_T *) &mcontext->__fs; uint64_t *xp = (uint64_t *) &avx_state->__fpu_xmm7; uint64_t *yp = (uint64_t *) &avx_state->__fpu_ymmh7; uint64_t *zp = (uint64_t *) &avx_state->__fpu_zmmh7; uint64_t *kp = (uint64_t *) &avx_state->__fpu_k0; /* Check for AVX512 state */ T_QUIET; T_ASSERT_GE(contextp->uc_mcsize, MCONTEXT_SIZE_512, "check context size"); /* Check that the state in the context is what's set and expected */ copy_zmm_state_to_vector(avx_state, vec512array3); assert_zmm_eq(vec512array3, vec512array0, sizeof(vec512array3)); copy_state_to_opmask(avx_state, karray3); assert_opmask_eq(karray3, karray0); /* Change the context and break the main loop */ checking = FALSE; } void zmm_integrity(int time) { mach_msg_type_number_t avx_count = X86_AVX512_STATE_COUNT; kern_return_t kret; X86_AVX512_STATE_T avx_state, avx_state2; mach_port_t ts = mach_thread_self(); bzero(&avx_state, sizeof(avx_state)); bzero(&avx_state2, sizeof(avx_state)); store_zmm(vec512array2); store_opmask(karray2); kret = _thread_get_state_avx512( ts, X86_AVX512_STATE_FLAVOR, (thread_state_t)&avx_state, &avx_count ); T_QUIET; T_ASSERT_MACH_SUCCESS(kret, "thread_get_state()"); vec512_to_string(vec512array2, vec_str_buf); opmask_to_string(karray2, karray_str_buf); T_LOG("Initial state:\n%s\n%s", vec_str_buf, karray_str_buf); copy_zmm_state_to_vector(&avx_state, vec512array1); assert_zmm_eq(vec512array2, vec512array1, sizeof(vec512array1)); copy_state_to_opmask(&avx_state, karray1); assert_opmask_eq(karray2, karray1); populate_zmm(); populate_opmask(); kret = _thread_get_state_avx512( ts, X86_AVX512_STATE_FLAVOR, (thread_state_t)&avx_state2, &avx_count ); store_zmm(vec512array2); store_opmask(karray2); T_QUIET; T_ASSERT_MACH_SUCCESS(kret, "thread_get_state()"); vec512_to_string(vec512array2, vec_str_buf); opmask_to_string(karray2, karray_str_buf); T_LOG("Populated state:\n%s\n%s", vec_str_buf, karray_str_buf); copy_zmm_state_to_vector(&avx_state2, vec512array1); assert_zmm_eq(vec512array2, vec512array1, sizeof(vec512array1)); copy_state_to_opmask(&avx_state2, karray1); assert_opmask_eq(karray2, karray1); T_LOG("Running for %ds…", time); start_timer(time, zmm_sigalrm_handler); /* re-populate because printing mucks up XMMs */ populate_zmm(); populate_opmask(); /* Check state until timer fires */ while (checking) { check_zmm(TRUE); } /* Check that the sig handler changed our AVX state */ store_zmm(vec512array1); store_opmask(karray1); uint64_t *p = (uint64_t *) &vec512array1[7]; if (p[0] != STOP_COOKIE_512 || p[2] != STOP_COOKIE_512 || p[4] != STOP_COOKIE_512 || karray1[7] != STOP_COOKIE_512) { vec512_to_string(vec512array1, vec_str_buf); opmask_to_string(karray1, karray_str_buf); T_ASSERT_FAIL("sigreturn failed to stick"); T_LOG("State:\n%s\n%s", vec_str_buf, karray_str_buf); } T_LOG("Ran for %ds", time); T_PASS("No zmm register corruption occurred"); } void zmm_zeroing_optimization_integrity(int time) { /* * Check ZMM zero and OpMask zero */ T_LOG("Checking ZMM zero and OpMask zero"); checking = true; zero_zmm(); zero_opmask(); T_LOG("Running for %ds…", time); start_timer(time, zmm_sigalrm_handler_no_mod); /* re-populate because printing mucks up XMMs */ zero_zmm(); zero_opmask(); /* Check state until timer fires */ while (checking) { check_zmm(FALSE); } /* Check that sig handler did not changed our AVX state */ store_zmm(vec512array2); store_opmask(karray2); assert_zmm_eq(vec512array0, vec512array2, sizeof(vec512array2)); assert_opmask_eq(karray0, karray2); T_LOG("Ran for %ds", time); T_PASS("ZMM zero and OpMask zero"); /* * Check ZMM zero and OpMask non-zero */ T_LOG("Checking ZMM zero and OpMask non-zero"); checking = true; zero_zmm(); populate_opmask(); T_LOG("Running for %ds…", time); start_timer(time, zmm_sigalrm_handler_no_mod); /* re-populate because printing mucks up XMMs */ zero_zmm(); populate_opmask(); /* Check state until timer fires */ while (checking) { check_zmm(FALSE); } /* Check that sig handler did not changed our AVX state */ store_zmm(vec512array2); store_opmask(karray2); assert_zmm_eq(vec512array0, vec512array2, sizeof(vec512array2)); assert_opmask_eq(karray0, karray2); T_LOG("Ran for %ds", time); T_PASS("ZMM zero and OpMask non-zero"); /* * Check ZMM non-zero and OpMask zero */ T_LOG("Checking ZMM non-zero and OpMask zero"); checking = true; populate_zmm(); zero_opmask(); T_LOG("Running for %ds…", time); start_timer(time, zmm_sigalrm_handler_no_mod); /* re-populate because printing mucks up XMMs */ populate_zmm(); zero_opmask(); /* Check state until timer fires */ while (checking) { check_zmm(FALSE); } /* Check that sig handler did not changed our AVX state */ store_zmm(vec512array2); store_opmask(karray2); assert_zmm_eq(vec512array0, vec512array2, sizeof(vec512array2)); assert_opmask_eq(karray0, karray2); T_LOG("Ran for %ds", time); T_PASS("ZMM non-zero and OpMask zero"); /* * Check ZMM non-zero and OpMask non-zero */ T_LOG("Checking ZMM non-zero and OpMask non-zero"); checking = true; populate_zmm(); populate_opmask(); T_LOG("Running for %ds…", time); start_timer(time, zmm_sigalrm_handler_no_mod); /* re-populate because printing mucks up XMMs */ populate_zmm(); populate_opmask(); /* Check state until timer fires */ while (checking) { check_zmm(FALSE); } /* Check that sig handler did not changed our AVX state */ store_zmm(vec512array2); store_opmask(karray2); assert_zmm_eq(vec512array0, vec512array2, sizeof(vec512array2)); assert_opmask_eq(karray0, karray2); T_LOG("Ran for %ds", time); T_PASS("ZMM non-zero and OpMask non-zero"); } /* * Main test declarations */ T_DECL(ymm_integrity, "Quick soak test to verify that AVX " "register state is maintained correctly", T_META_TIMEOUT(NORMAL_RUN_TIME + TIMEOUT_OVERHEAD)) { require_avx(); ymm_integrity(NORMAL_RUN_TIME); } T_DECL(ymm_integrity_stress, "Extended soak test to verify that AVX " "register state is maintained correctly", T_META_TIMEOUT(LONG_RUN_TIME + TIMEOUT_OVERHEAD), T_META_ENABLED(false)) { require_avx(); ymm_integrity(LONG_RUN_TIME); } T_DECL(zmm_integrity, "Quick soak test to verify that AVX-512 " "register state is maintained correctly", T_META_TIMEOUT(NORMAL_RUN_TIME + TIMEOUT_OVERHEAD)) { require_avx512(); zmm_integrity(NORMAL_RUN_TIME); } T_DECL(zmm_integrity_stress, "Extended soak test to verify that AVX-512 " "register state is maintained correctly", T_META_TIMEOUT(LONG_RUN_TIME + TIMEOUT_OVERHEAD), T_META_ENABLED(false)) { require_avx512(); zmm_integrity(LONG_RUN_TIME); } T_DECL(zmm_zeroing_optimization_integrity, "Quick soak test to verify AVX-512 " "register state is maintained with " "zeroing optimizations enabled", T_META_TIMEOUT(QUICK_RUN_TIME + TIMEOUT_OVERHEAD)) { require_avx512(); zmm_zeroing_optimization_integrity(QUICK_RUN_TIME); } |