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286 lines
6.9 KiB
C++
286 lines
6.9 KiB
C++
#include "stdafx.h"
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#include "sys_time.h"
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#include "Emu/system_config.h"
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#include "Emu/Cell/ErrorCodes.h"
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#include "util/asm.hpp"
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#ifdef _WIN32
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#include <Windows.h>
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struct time_aux_info_t
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{
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u64 perf_freq;
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u64 start_time;
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u64 start_ftime; // time in 100ns units since Epoch
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};
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// Initialize time-related values
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const auto s_time_aux_info = []() -> time_aux_info_t
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{
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LARGE_INTEGER freq;
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if (!QueryPerformanceFrequency(&freq))
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{
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MessageBox(0, L"Your hardware doesn't support a high-resolution performance counter", L"Error", MB_OK | MB_ICONERROR);
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return {};
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}
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LARGE_INTEGER start;
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QueryPerformanceCounter(&start); // get time in 1/perf_freq units from RDTSC
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FILETIME ftime;
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GetSystemTimeAsFileTime(&ftime); // get time in 100ns units since January 1, 1601 (UTC)
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time_aux_info_t result;
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result.perf_freq = freq.QuadPart;
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result.start_time = start.QuadPart;
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result.start_ftime = (ftime.dwLowDateTime | (u64)ftime.dwHighDateTime << 32) - 116444736000000000;
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return result;
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}();
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#elif __APPLE__
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// XXX only supports a single timer
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#define TIMER_ABSTIME -1
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// The opengroup spec isn't clear on the mapping from REALTIME to CALENDAR being appropriate or not.
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// http://pubs.opengroup.org/onlinepubs/009695299/basedefs/time.h.html
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#define CLOCK_REALTIME 1 // #define CALENDAR_CLOCK 1 from mach/clock_types.h
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#define CLOCK_MONOTONIC 0 // #define SYSTEM_CLOCK 0
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// the mach kernel uses struct mach_timespec, so struct timespec is loaded from <sys/_types/_timespec.h> for compatability
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// struct timespec { time_t tv_sec; long tv_nsec; };
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#include <sys/types.h>
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#include <sys/_types/_timespec.h>
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#include <mach/mach.h>
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#include <mach/clock.h>
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#include <mach/mach_time.h>
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#undef CPU_STATE_MAX
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#define MT_NANO (+1.0E-9)
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#define MT_GIGA UINT64_C(1000000000)
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// TODO create a list of timers,
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static double mt_timebase = 0.0;
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static u64 mt_timestart = 0;
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static int clock_gettime(int clk_id, struct timespec* tp)
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{
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kern_return_t retval = KERN_SUCCESS;
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if (clk_id == TIMER_ABSTIME)
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{
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if (!mt_timestart)
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{
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// only one timer, initilized on the first call to the TIMER
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mach_timebase_info_data_t tb = {0};
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mach_timebase_info(&tb);
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mt_timebase = tb.numer;
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mt_timebase /= tb.denom;
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mt_timestart = mach_absolute_time();
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}
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double diff = (mach_absolute_time() - mt_timestart) * mt_timebase;
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tp->tv_sec = diff * MT_NANO;
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tp->tv_nsec = diff - (tp->tv_sec * MT_GIGA);
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}
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else // other clk_ids are mapped to the coresponding mach clock_service
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{
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clock_serv_t cclock;
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mach_timespec_t mts;
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host_get_clock_service(mach_host_self(), clk_id, &cclock);
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retval = clock_get_time(cclock, &mts);
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mach_port_deallocate(mach_task_self(), cclock);
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tp->tv_sec = mts.tv_sec;
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tp->tv_nsec = mts.tv_nsec;
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}
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return retval;
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}
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#endif
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#ifndef _WIN32
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static struct timespec start_time = []()
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{
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struct timespec ts;
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if (::clock_gettime(CLOCK_REALTIME, &ts) != 0)
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{
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// Fatal error
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std::terminate();
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}
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return ts;
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}();
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#endif
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LOG_CHANNEL(sys_time);
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static constexpr u64 g_timebase_freq = /*79800000*/ 80000000ull; // 80 Mhz
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// Auxiliary functions
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u64 get_timebased_time()
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{
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#ifdef _WIN32
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LARGE_INTEGER count;
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ensure(QueryPerformanceCounter(&count));
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const u64 time = count.QuadPart;
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const u64 freq = s_time_aux_info.perf_freq;
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return (time / freq * g_timebase_freq + time % freq * g_timebase_freq / freq) * g_cfg.core.clocks_scale / 100u;
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#else
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struct timespec ts;
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ensure(::clock_gettime(CLOCK_MONOTONIC, &ts) == 0);
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return (static_cast<u64>(ts.tv_sec) * g_timebase_freq + static_cast<u64>(ts.tv_nsec) * g_timebase_freq / 1000000000ull) * g_cfg.core.clocks_scale / 100u;
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#endif
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}
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// Returns some relative time in microseconds, don't change this fact
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u64 get_system_time()
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{
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while (true)
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{
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#ifdef _WIN32
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LARGE_INTEGER count;
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ensure(QueryPerformanceCounter(&count));
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const u64 time = count.QuadPart;
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const u64 freq = s_time_aux_info.perf_freq;
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const u64 result = time / freq * 1000000ull + (time % freq) * 1000000ull / freq;
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#else
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struct timespec ts;
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ensure(::clock_gettime(CLOCK_MONOTONIC, &ts) == 0);
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const u64 result = static_cast<u64>(ts.tv_sec) * 1000000ull + static_cast<u64>(ts.tv_nsec) / 1000u;
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#endif
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if (result) return result;
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}
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}
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// As get_system_time but obeys Clocks scaling setting
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u64 get_guest_system_time()
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{
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return get_system_time() * g_cfg.core.clocks_scale / 100;
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}
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// Functions
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error_code sys_time_get_timezone(vm::ptr<s32> timezone, vm::ptr<s32> summertime)
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{
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sys_time.warning("sys_time_get_timezone(timezone=*0x%x, summertime=*0x%x)", timezone, summertime);
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*timezone = 180;
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*summertime = 0;
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return CELL_OK;
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}
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error_code sys_time_get_current_time(vm::ptr<s64> sec, vm::ptr<s64> nsec)
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{
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sys_time.trace("sys_time_get_current_time(sec=*0x%x, nsec=*0x%x)", sec, nsec);
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if (!sec)
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{
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return CELL_EFAULT;
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}
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#ifdef _WIN32
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LARGE_INTEGER count;
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ensure(QueryPerformanceCounter(&count));
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const u64 diff_base = count.QuadPart - s_time_aux_info.start_time;
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// Get time difference in nanoseconds (using 128 bit accumulator)
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const u64 diff_sl = diff_base * 1000000000ull;
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const u64 diff_sh = utils::umulh64(diff_base, 1000000000ull);
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const u64 diff = utils::udiv128(diff_sh, diff_sl, s_time_aux_info.perf_freq);
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// get time since Epoch in nanoseconds
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const u64 time = s_time_aux_info.start_ftime * 100u + (diff * g_cfg.core.clocks_scale / 100u);
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// scale to seconds, and add the console time offset (which might be negative)
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*sec = (time / 1000000000ull) + g_cfg.sys.console_time_offset;
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if (!nsec)
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{
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return CELL_EFAULT;
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}
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*nsec = time % 1000000000ull;
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#else
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struct timespec ts;
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ensure(::clock_gettime(CLOCK_REALTIME, &ts) == 0);
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if (g_cfg.core.clocks_scale == 100)
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{
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// get the seconds from the system clock, and add the console time offset (which might be negative)
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*sec = ts.tv_sec + g_cfg.sys.console_time_offset;
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if (!nsec)
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{
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return CELL_EFAULT;
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}
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*nsec = ts.tv_nsec;
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return CELL_OK;
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}
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u64 tv_sec = ts.tv_sec, stv_sec = start_time.tv_sec;
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u64 tv_nsec = ts.tv_nsec, stv_nsec = start_time.tv_nsec;
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// Substruct time since Epoch and since start time
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tv_sec -= stv_sec;
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if (tv_nsec < stv_nsec)
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{
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// Correct value if borrow encountered
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tv_sec -= 1;
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tv_nsec = 1'000'000'000ull - (stv_nsec - tv_nsec);
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}
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else
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{
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tv_nsec -= stv_nsec;
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}
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// Scale nanocseconds
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tv_nsec = stv_nsec + (tv_nsec * g_cfg.core.clocks_scale / 100);
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// Scale seconds and add from nanoseconds / 1'000'000'000, and add the console time offset (which might be negative)
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*sec = stv_sec + (tv_sec * g_cfg.core.clocks_scale / 100u) + (tv_nsec / 1000000000ull) + g_cfg.sys.console_time_offset;
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if (!nsec)
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{
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return CELL_EFAULT;
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}
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// Set nanoseconds
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*nsec = tv_nsec % 1000000000ull;
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#endif
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return CELL_OK;
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}
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u64 sys_time_get_timebase_frequency()
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{
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sys_time.trace("sys_time_get_timebase_frequency()");
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return g_timebase_freq;
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}
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error_code sys_time_get_rtc(vm::ptr<u64> rtc)
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{
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sys_time.todo("sys_time_get_rtc(rtc=*0x%x)", rtc);
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return CELL_OK;
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}
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