#include "monotonic.h" #include #include #include #include #undef NDEBUG #include #if defined(_WIN32) || defined(_WIN64) #include "msvcTime.h" #include "msvcStdio.h" #endif /* The function pointer for clock retrieval. */ monotime (*getMonotonicUs)(void) = NULL; static char monotonic_info_string[32]; /* Using the processor clock (aka TSC on x86) can provide improved performance * throughout Redis wherever the monotonic clock is used. The processor clock * is significantly faster than calling 'clock_getting' (POSIX). While this is * generally safe on modern systems, this link provides additional information * about use of the x86 TSC: http://oliveryang.net/2015/09/pitfalls-of-TSC-usage * * To use the processor clock, either uncomment this line, or build with * CFLAGS="-DUSE_PROCESSOR_CLOCK" #define USE_PROCESSOR_CLOCK */ #if defined(USE_PROCESSOR_CLOCK) && defined(__x86_64__) && defined(__linux__) #include #include static long mono_ticksPerMicrosecond = 0; #ifdef _TD_NINGSI_60 // implement __rdtsc in ningsi60 uint64_t __rdtsc(){ unsigned int lo,hi; __asm__ __volatile__ ("rdtsc" : "=a" (lo), "=d" (hi)); return ((uint64_t)hi << 32) | lo; } #endif static monotime getMonotonicUs_x86() { return __rdtsc() / mono_ticksPerMicrosecond; } static void monotonicInit_x86linux() { const int bufflen = 256; char buf[bufflen]; regex_t cpuGhzRegex, constTscRegex; const size_t nmatch = 2; regmatch_t pmatch[nmatch]; int constantTsc = 0; int rc; /* Determine the number of TSC ticks in a micro-second. This is * a constant value matching the standard speed of the processor. * On modern processors, this speed remains constant even though * the actual clock speed varies dynamically for each core. */ rc = regcomp(&cpuGhzRegex, "^model name\\s+:.*@ ([0-9.]+)GHz", REG_EXTENDED); assert(rc == 0); /* Also check that the constant_tsc flag is present. (It should be * unless this is a really old CPU. */ rc = regcomp(&constTscRegex, "^flags\\s+:.* constant_tsc", REG_EXTENDED); assert(rc == 0); FILE *cpuinfo = fopen("/proc/cpuinfo", "r"); if (cpuinfo != NULL) { while (fgets(buf, bufflen, cpuinfo) != NULL) { if (regexec(&cpuGhzRegex, buf, nmatch, pmatch, 0) == 0) { buf[pmatch[1].rm_eo] = '\0'; double ghz = atof(&buf[pmatch[1].rm_so]); mono_ticksPerMicrosecond = (long)(ghz * 1000); break; } } while (fgets(buf, bufflen, cpuinfo) != NULL) { if (regexec(&constTscRegex, buf, nmatch, pmatch, 0) == 0) { constantTsc = 1; break; } } fclose(cpuinfo); } regfree(&cpuGhzRegex); regfree(&constTscRegex); if (mono_ticksPerMicrosecond == 0) { //fprintf(stderr, "monotonic: x86 linux, unable to determine clock rate"); return; } if (!constantTsc) { //fprintf(stderr, "monotonic: x86 linux, 'constant_tsc' flag not present"); return; } snprintf(monotonic_info_string, sizeof(monotonic_info_string), "X86 TSC @ %ld ticks/us", mono_ticksPerMicrosecond); getMonotonicUs = getMonotonicUs_x86; } #endif #if defined(USE_PROCESSOR_CLOCK) && defined(__aarch64__) static long mono_ticksPerMicrosecond = 0; /* Read the clock value. */ static inline uint64_t __cntvct() { uint64_t virtual_timer_value; __asm__ volatile("mrs %0, cntvct_el0" : "=r"(virtual_timer_value)); return virtual_timer_value; } /* Read the Count-timer Frequency. */ static inline uint32_t cntfrq_hz() { uint64_t virtual_freq_value; __asm__ volatile("mrs %0, cntfrq_el0" : "=r"(virtual_freq_value)); return (uint32_t)virtual_freq_value; /* top 32 bits are reserved */ } static monotime getMonotonicUs_aarch64() { return __cntvct() / mono_ticksPerMicrosecond; } static void monotonicInit_aarch64() { mono_ticksPerMicrosecond = (long)cntfrq_hz() / 1000L / 1000L; if (mono_ticksPerMicrosecond == 0) { fprintf(stderr, "monotonic: aarch64, unable to determine clock rate"); return; } snprintf(monotonic_info_string, sizeof(monotonic_info_string), "ARM CNTVCT @ %ld ticks/us", mono_ticksPerMicrosecond); getMonotonicUs = getMonotonicUs_aarch64; } #endif static monotime getMonotonicUs_posix(void) { /* clock_gettime() is specified in POSIX.1b (1993). Even so, some systems * did not support this until much later. CLOCK_MONOTONIC is technically * optional and may not be supported - but it appears to be universal. * If this is not supported, provide a system-specific alternate version. */ struct timespec ts; clock_gettime(CLOCK_MONOTONIC, &ts); return ((uint64_t)ts.tv_sec) * 1000000 + ts.tv_nsec / 1000; } static void monotonicInit_posix() { /* Ensure that CLOCK_MONOTONIC is supported. This should be supported * on any reasonably current OS. If the assertion below fails, provide * an appropriate alternate implementation. */ struct timespec ts; int rc = clock_gettime(CLOCK_MONOTONIC, &ts); assert(rc == 0); snprintf(monotonic_info_string, sizeof(monotonic_info_string), "POSIX clock_gettime"); getMonotonicUs = getMonotonicUs_posix; } const char * monotonicInit() { #if defined(USE_PROCESSOR_CLOCK) && defined(__x86_64__) && defined(__linux__) if (getMonotonicUs == NULL) monotonicInit_x86linux(); #endif #if defined(USE_PROCESSOR_CLOCK) && defined(__aarch64__) if (getMonotonicUs == NULL) monotonicInit_aarch64(); #endif if (getMonotonicUs == NULL) monotonicInit_posix(); return monotonic_info_string; }