//========= Copyright Valve Corporation, All rights reserved. ============// // // Purpose: determine CPU speed under linux // // $NoKeywords: $ //=============================================================================// #include #include #include #ifdef LINUX #include #else #include # ifdef __APPLE__ # define CPUFREQ_SYSCTL "hw.cpufrequency_max" # else # define CPUFREQ_SYSCTL "dev.cpu.0.freq" # endif #endif #include #include #include #include #define rdtsc(x) \ __asm__ __volatile__ ("rdtsc" : "=A" (x)) class TimeVal { public: TimeVal() {} TimeVal& operator=(const TimeVal &val) { m_TimeVal = val.m_TimeVal; return *this; } inline double operator-(const TimeVal &left) { uint64 left_us = (uint64) left.m_TimeVal.tv_sec * 1000000 + left.m_TimeVal.tv_usec; uint64 right_us = (uint64) m_TimeVal.tv_sec * 1000000 + m_TimeVal.tv_usec; uint64 diff_us = right_us - left_us; return diff_us * ( 1.0 / 1000000.0 ); } timeval m_TimeVal; }; // Compute the positive difference between two 64 bit numbers. static inline uint64 diff(uint64 v1, uint64 v2) { int64 d = v1 - v2; if (d >= 0) return d; else return -d; } #if defined(OSX) || defined(PLATFORM_BSD) // Mac or BSD uint64 GetCPUFreqFromPROC() { uint64 freq_hz = 0; size_t freq_size = sizeof(freq_hz); int retval = sysctlbyname(CPUFREQ_SYSCTL, &freq_hz, &freq_size, NULL, 0); return freq_hz; } #else // Linux uint64 GetCPUFreqFromPROC() { double mhz = 0; char line[1024], *s, search_str[] = "cpu MHz"; /* open proc/cpuinfo */ FILE *fp = fopen( "/proc/cpuinfo", "r" ); if (fp == NULL) { return 0; } /* ignore all lines until we reach MHz information */ while (fgets(line, 1024, fp) != NULL) { if (strstr(line, search_str) != NULL) { /* ignore all characters in line up to : */ for (s = line; *s && (*s != ':'); ++s) ; /* get MHz number */ if ( *s && ( sscanf( s + 1, "%lf", &mhz) == 1 ) ) break; } } fclose(fp); return ( uint64 )( mhz * 1000000 ); } #endif uint64 CalculateCPUFreq() { #if defined(__APPLE__) || defined(PLATFORM_BSD) return GetCPUFreqFromPROC(); #else // Try to open cpuinfo_max_freq. If the kernel was built with cpu scaling support disabled, this will fail. FILE *fp = fopen( "/sys/devices/system/cpu/cpu0/cpufreq/cpuinfo_max_freq", "r" ); if ( fp ) { char buf[ 256 ]; uint64 retVal = 0; buf[ 0 ] = 0; if( fread( buf, 1, ARRAYSIZE( buf ), fp ) ) { retVal = ( uint64 )atoll( buf ); } fclose(fp); if( retVal ) { return retVal * 1000; } } #if defined(__i386__) || defined(_M_IX86) // fallback mechanism to calculate when failed // Compute the period. Loop until we get 3 consecutive periods that // are the same to within a small error. The error is chosen // to be +/- 0.02% on a P-200. const uint64 error = 40000; const int max_iterations = 600; int count; uint64 period, period1 = error * 2, period2 = 0, period3 = 0; for (count = 0; count < max_iterations; count++) { TimeVal start_time, end_time; uint64 start_tsc, end_tsc; gettimeofday( &start_time.m_TimeVal, 0 ); rdtsc( start_tsc ); usleep( 5000 ); // sleep for 5 msec gettimeofday( &end_time.m_TimeVal, 0 ); rdtsc( end_tsc ); // end_time - start_time calls into the overloaded TimeVal operator- way above, and returns a double. period3 = ( end_tsc - start_tsc ) / ( end_time - start_time ); if (diff ( period1, period2 ) <= error && diff ( period2, period3 ) <= error && diff ( period1, period3 ) <= error ) { break; } period1 = period2; period2 = period3; } if ( count == max_iterations ) { return GetCPUFreqFromPROC(); // fall back to /proc } // Set the period to the average period measured. period = ( period1 + period2 + period3 ) / 3; // Some Pentiums have broken TSCs that increment very // slowly or unevenly. if (period < 10000000) { return GetCPUFreqFromPROC(); // fall back to /proc } return period; #else // ARM hard-coded frequency return (uint64)2000000000; #endif // if i386 #endif // if APPLE }