#include "StdAfx.h" #include "utypes.h" #include #include #ifdef WIN32 #define WIN32_LEAN_AND_MEAN #include #include #include typedef ULONGLONG (WINAPI GetTickCount64Proc)(void); static GetTickCount64Proc *pt2GetTickCount64; static GetTickCount64Proc *pt2RealGetTickCount; static uint64 startPerformanceCounter; static uint64 startGetTickCount; // MSVC 6 standard doesn't like division with uint64s static double counterPerMicrosecond; uint64 UTGetTickCount64() { if (pt2GetTickCount64) { return pt2GetTickCount64(); } if (pt2RealGetTickCount) { uint64 v = pt2RealGetTickCount(); // fix return value from GetTickCount return (DWORD)v | ((v >> 0x18) & 0xFFFFFFFF00000000); } return (uint64)GetTickCount(); } void Time_Initialize() { HMODULE kernel32 = GetModuleHandleA("kernel32.dll"); pt2GetTickCount64 = (GetTickCount64Proc*)GetProcAddress(kernel32, "GetTickCount64"); // not a typo. GetTickCount actually returns 64 bits pt2RealGetTickCount = (GetTickCount64Proc*)GetProcAddress(kernel32, "GetTickCount"); uint64 frequency; QueryPerformanceCounter((LARGE_INTEGER*)&startPerformanceCounter); QueryPerformanceFrequency((LARGE_INTEGER*)&frequency); counterPerMicrosecond = (double)frequency / 1000000.0f; startGetTickCount = UTGetTickCount64(); } int64 abs64(int64 x) { return x < 0 ? -x : x; } static uint64 GetMicroseconds() { static bool time_init = false; if (!time_init) { time_init = true; Time_Initialize(); } uint64 counter; uint64 tick; QueryPerformanceCounter((LARGE_INTEGER*) &counter); tick = UTGetTickCount64(); // unfortunately, QueryPerformanceCounter is not guaranteed // to be monotonic. Make it so. int64 ret = (int64)(((int64)counter - (int64)startPerformanceCounter) / counterPerMicrosecond); // if the QPC clock leaps more than one second off GetTickCount64() // something is seriously fishy. Adjust QPC to stay monotonic int64 tick_diff = tick - startGetTickCount; if (abs64(ret / 100000 - tick_diff / 100) > 10) { startPerformanceCounter -= (uint64)((int64)(tick_diff * 1000 - ret) * counterPerMicrosecond); ret = (int64)((counter - startPerformanceCounter) / counterPerMicrosecond); } return ret; } #else //!WIN32 #include #include // Linux needs both time.h and sys/time.h #include #include #include #include #if defined(__APPLE__) #include static uint64 GetMicroseconds() { // http://developer.apple.com/mac/library/qa/qa2004/qa1398.html // http://www.macresearch.org/tutorial_performance_and_time static mach_timebase_info_data_t sTimebaseInfo; static uint64_t start_tick = 0; uint64_t tick; // Returns a counter in some fraction of a nanoseconds tick = mach_absolute_time(); if (sTimebaseInfo.denom == 0) { // Get the timer ratio to convert mach_absolute_time to nanoseconds mach_timebase_info(&sTimebaseInfo); start_tick = tick; } // Calculate the elapsed time, convert it to microseconds and return it. return ((tick - start_tick) * sTimebaseInfo.numer) / (sTimebaseInfo.denom * 1000); } #else //!__APPLE__ /* Unfortunately, #ifdef CLOCK_MONOTONIC is not enough to make sure that POSIX clocks work -- we could be running a recent libc with an ancient kernel (think OpenWRT). -- jch */ static uint64_t GetMicroseconds() { static int have_posix_clocks = -1; int rc; #if defined(_POSIX_TIMERS) && _POSIX_TIMERS > 0 && defined(CLOCK_MONOTONIC) if (have_posix_clocks < 0) { struct timespec ts; rc = clock_gettime(CLOCK_MONOTONIC, &ts); if (rc < 0) { have_posix_clocks = 0; } else { have_posix_clocks = 1; } } if (have_posix_clocks) { struct timespec ts; rc = clock_gettime(CLOCK_MONOTONIC, &ts); return uint64(ts.tv_sec) * 1000000 + ts.tv_nsec / 1000; } #endif { struct timeval tv; rc = gettimeofday(&tv, NULL); return uint64(tv.tv_sec) * 1000000 + tv.tv_usec; } } #endif //!__APPLE__ #endif //!WIN32 uint64 UTP_GetMicroseconds() { static uint64 offset = 0, previous = 0; uint64 now = GetMicroseconds() + offset; if (previous > now) { /* Eek! */ offset += previous - now; now = previous; } previous = now; return now; } uint32 UTP_GetMilliseconds() { return UTP_GetMicroseconds() / 1000; } #define ETHERNET_MTU 1500 #define IPV4_HEADER_SIZE 20 #define IPV6_HEADER_SIZE 40 #define UDP_HEADER_SIZE 8 #define GRE_HEADER_SIZE 24 #define PPPOE_HEADER_SIZE 8 #define MPPE_HEADER_SIZE 2 // packets have been observed in the wild that were fragmented // with a payload of 1416 for the first fragment // There are reports of routers that have MTU sizes as small as 1392 #define FUDGE_HEADER_SIZE 36 #define TEREDO_MTU 1280 #define UDP_IPV4_OVERHEAD (IPV4_HEADER_SIZE + UDP_HEADER_SIZE) #define UDP_IPV6_OVERHEAD (IPV6_HEADER_SIZE + UDP_HEADER_SIZE) #define UDP_TEREDO_OVERHEAD (UDP_IPV4_OVERHEAD + UDP_IPV6_OVERHEAD) #define UDP_IPV4_MTU (ETHERNET_MTU - IPV4_HEADER_SIZE - UDP_HEADER_SIZE - GRE_HEADER_SIZE - PPPOE_HEADER_SIZE - MPPE_HEADER_SIZE - FUDGE_HEADER_SIZE) #define UDP_IPV6_MTU (ETHERNET_MTU - IPV6_HEADER_SIZE - UDP_HEADER_SIZE - GRE_HEADER_SIZE - PPPOE_HEADER_SIZE - MPPE_HEADER_SIZE - FUDGE_HEADER_SIZE) #define UDP_TEREDO_MTU (TEREDO_MTU - IPV6_HEADER_SIZE - UDP_HEADER_SIZE) uint16 UTP_GetUDPMTU(const struct sockaddr *remote, socklen_t remotelen) { // Since we don't know the local address of the interface, // be conservative and assume all IPv6 connections are Teredo. return remote->sa_family == AF_INET6 ? UDP_TEREDO_MTU : UDP_IPV4_MTU; } uint16 UTP_GetUDPOverhead(const struct sockaddr *remote, socklen_t remotelen) { // Since we don't know the local address of the interface, // be conservative and assume all IPv6 connections are Teredo. return remote->sa_family == AF_INET6 ? UDP_TEREDO_OVERHEAD : UDP_IPV4_OVERHEAD; } uint32 UTP_Random() { return rand(); } void UTP_DelaySample(const struct sockaddr *remote, int sample_ms) {} size_t UTP_GetPacketSize(const struct sockaddr *remote) { return 1500; }