third_party/musl/src/linux/clock_adjtime.c - cobalt - Git at Google

 #include <sys/timex.h>
 #include <time.h>
 #include <errno.h>
 #include "syscall.h"

 #define IS32BIT(x) !((x)+0x80000000ULL>>32)

 struct ktimex64 {
 	unsigned modes;
 	int :32;
 	long long offset, freq, maxerror, esterror;
 	int status;
 	int :32;
 	long long constant, precision, tolerance;
 	long long time_sec, time_usec;
 	long long tick, ppsfreq, jitter;
 	int shift;
 	int :32;
 	long long stabil, jitcnt, calcnt, errcnt, stbcnt;
 	int tai;
 	int __padding[11];
 };

 struct ktimex {
 	unsigned modes;
 	long offset, freq, maxerror, esterror;
 	int status;
 	long constant, precision, tolerance;
 	long time_sec, time_usec;
 	long tick, ppsfreq, jitter;
 	int shift;
 	long stabil, jitcnt, calcnt, errcnt, stbcnt;
 	int tai;
 	int __padding[11];
 };

 int clock_adjtime (clockid_t clock_id, struct timex *utx)
 {
 	int r = -ENOSYS;
 #ifdef SYS_clock_adjtime64
 	struct ktimex64 ktx = {
 		.modes = utx->modes,
 		.offset = utx->offset,
 		.freq = utx->freq,
 		.maxerror = utx->maxerror,
 		.esterror = utx->esterror,
 		.status = utx->status,
 		.constant = utx->constant,
 		.precision = utx->precision,
 		.tolerance = utx->tolerance,
 		.time_sec = utx->time.tv_sec,
 		.time_usec = utx->time.tv_usec,
 		.tick = utx->tick,
 		.ppsfreq = utx->ppsfreq,
 		.jitter = utx->jitter,
 		.shift = utx->shift,
 		.stabil = utx->stabil,
 		.jitcnt = utx->jitcnt,
 		.calcnt = utx->calcnt,
 		.errcnt = utx->errcnt,
 		.stbcnt = utx->stbcnt,
 		.tai = utx->tai,
 	};
 	r = __syscall(SYS_clock_adjtime64, clock_id, &ktx);
 	if (r>=0) {
 		utx->modes = ktx.modes;
 		utx->offset = ktx.offset;
 		utx->freq = ktx.freq;
 		utx->maxerror = ktx.maxerror;
 		utx->esterror = ktx.esterror;
 		utx->status = ktx.status;
 		utx->constant = ktx.constant;
 		utx->precision = ktx.precision;
 		utx->tolerance = ktx.tolerance;
 		utx->time.tv_sec = ktx.time_sec;
 		utx->time.tv_usec = ktx.time_usec;
 		utx->tick = ktx.tick;
 		utx->ppsfreq = ktx.ppsfreq;
 		utx->jitter = ktx.jitter;
 		utx->shift = ktx.shift;
 		utx->stabil = ktx.stabil;
 		utx->jitcnt = ktx.jitcnt;
 		utx->calcnt = ktx.calcnt;
 		utx->errcnt = ktx.errcnt;
 		utx->stbcnt = ktx.stbcnt;
 		utx->tai = ktx.tai;
 	}
 	if (SYS_clock_adjtime == SYS_clock_adjtime64 || r!=-ENOSYS)
 		return __syscall_ret(r);
 	if ((utx->modes & ADJ_SETOFFSET) && !IS32BIT(utx->time.tv_sec))
 		return __syscall_ret(-ENOTSUP);
 #endif
 	if (sizeof(time_t) > sizeof(long)) {
 		struct ktimex ktx = {
 			.modes = utx->modes,
 			.offset = utx->offset,
 			.freq = utx->freq,
 			.maxerror = utx->maxerror,
 			.esterror = utx->esterror,
 			.status = utx->status,
 			.constant = utx->constant,
 			.precision = utx->precision,
 			.tolerance = utx->tolerance,
 			.time_sec = utx->time.tv_sec,
 			.time_usec = utx->time.tv_usec,
 			.tick = utx->tick,
 			.ppsfreq = utx->ppsfreq,
 			.jitter = utx->jitter,
 			.shift = utx->shift,
 			.stabil = utx->stabil,
 			.jitcnt = utx->jitcnt,
 			.calcnt = utx->calcnt,
 			.errcnt = utx->errcnt,
 			.stbcnt = utx->stbcnt,
 			.tai = utx->tai,
 		};
 #ifdef SYS_adjtimex
 		if (clock_id==CLOCK_REALTIME) r = __syscall(SYS_adjtimex, &ktx);
 		else
 #endif
 		r = __syscall(SYS_clock_adjtime, clock_id, &ktx);
 		if (r>=0) {
 			utx->modes = ktx.modes;
 			utx->offset = ktx.offset;
 			utx->freq = ktx.freq;
 			utx->maxerror = ktx.maxerror;
 			utx->esterror = ktx.esterror;
 			utx->status = ktx.status;
 			utx->constant = ktx.constant;
 			utx->precision = ktx.precision;
 			utx->tolerance = ktx.tolerance;
 			utx->time.tv_sec = ktx.time_sec;
 			utx->time.tv_usec = ktx.time_usec;
 			utx->tick = ktx.tick;
 			utx->ppsfreq = ktx.ppsfreq;
 			utx->jitter = ktx.jitter;
 			utx->shift = ktx.shift;
 			utx->stabil = ktx.stabil;
 			utx->jitcnt = ktx.jitcnt;
 			utx->calcnt = ktx.calcnt;
 			utx->errcnt = ktx.errcnt;
 			utx->stbcnt = ktx.stbcnt;
 			utx->tai = ktx.tai;
 		}
 		return __syscall_ret(r);
 	}
 #ifdef SYS_adjtimex
 	if (clock_id==CLOCK_REALTIME) return syscall(SYS_adjtimex, utx);
 #endif
 	return syscall(SYS_clock_adjtime, clock_id, utx);
 }
	#include <sys/timex.h>
	#include <time.h>
	#include <errno.h>
	#include "syscall.h"

	#define IS32BIT(x) !((x)+0x80000000ULL>>32)

	struct ktimex64 {
	unsigned modes;
	int :32;
	long long offset, freq, maxerror, esterror;
	int status;
	int :32;
	long long constant, precision, tolerance;
	long long time_sec, time_usec;
	long long tick, ppsfreq, jitter;
	int shift;
	int :32;
	long long stabil, jitcnt, calcnt, errcnt, stbcnt;
	int tai;
	int __padding[11];
	};

	struct ktimex {
	unsigned modes;
	long offset, freq, maxerror, esterror;
	int status;
	long constant, precision, tolerance;
	long time_sec, time_usec;
	long tick, ppsfreq, jitter;
	int shift;
	long stabil, jitcnt, calcnt, errcnt, stbcnt;
	int tai;
	int __padding[11];
	};

	int clock_adjtime (clockid_t clock_id, struct timex *utx)
	{
	int r = -ENOSYS;
	#ifdef SYS_clock_adjtime64
	struct ktimex64 ktx = {
	.modes = utx->modes,
	.offset = utx->offset,
	.freq = utx->freq,
	.maxerror = utx->maxerror,
	.esterror = utx->esterror,
	.status = utx->status,
	.constant = utx->constant,
	.precision = utx->precision,
	.tolerance = utx->tolerance,
	.time_sec = utx->time.tv_sec,
	.time_usec = utx->time.tv_usec,
	.tick = utx->tick,
	.ppsfreq = utx->ppsfreq,
	.jitter = utx->jitter,
	.shift = utx->shift,
	.stabil = utx->stabil,
	.jitcnt = utx->jitcnt,
	.calcnt = utx->calcnt,
	.errcnt = utx->errcnt,
	.stbcnt = utx->stbcnt,
	.tai = utx->tai,
	};
	r = __syscall(SYS_clock_adjtime64, clock_id, &ktx);
	if (r>=0) {
	utx->modes = ktx.modes;
	utx->offset = ktx.offset;
	utx->freq = ktx.freq;
	utx->maxerror = ktx.maxerror;
	utx->esterror = ktx.esterror;
	utx->status = ktx.status;
	utx->constant = ktx.constant;
	utx->precision = ktx.precision;
	utx->tolerance = ktx.tolerance;
	utx->time.tv_sec = ktx.time_sec;
	utx->time.tv_usec = ktx.time_usec;
	utx->tick = ktx.tick;
	utx->ppsfreq = ktx.ppsfreq;
	utx->jitter = ktx.jitter;
	utx->shift = ktx.shift;
	utx->stabil = ktx.stabil;
	utx->jitcnt = ktx.jitcnt;
	utx->calcnt = ktx.calcnt;
	utx->errcnt = ktx.errcnt;
	utx->stbcnt = ktx.stbcnt;
	utx->tai = ktx.tai;
	}
	if (SYS_clock_adjtime == SYS_clock_adjtime64 \|\| r!=-ENOSYS)
	return __syscall_ret(r);
	if ((utx->modes & ADJ_SETOFFSET) && !IS32BIT(utx->time.tv_sec))
	return __syscall_ret(-ENOTSUP);
	#endif
	if (sizeof(time_t) > sizeof(long)) {
	struct ktimex ktx = {
	.modes = utx->modes,
	.offset = utx->offset,
	.freq = utx->freq,
	.maxerror = utx->maxerror,
	.esterror = utx->esterror,
	.status = utx->status,
	.constant = utx->constant,
	.precision = utx->precision,
	.tolerance = utx->tolerance,
	.time_sec = utx->time.tv_sec,
	.time_usec = utx->time.tv_usec,
	.tick = utx->tick,
	.ppsfreq = utx->ppsfreq,
	.jitter = utx->jitter,
	.shift = utx->shift,
	.stabil = utx->stabil,
	.jitcnt = utx->jitcnt,
	.calcnt = utx->calcnt,
	.errcnt = utx->errcnt,
	.stbcnt = utx->stbcnt,
	.tai = utx->tai,
	};
	#ifdef SYS_adjtimex
	if (clock_id==CLOCK_REALTIME) r = __syscall(SYS_adjtimex, &ktx);
	else
	#endif
	r = __syscall(SYS_clock_adjtime, clock_id, &ktx);
	if (r>=0) {
	utx->modes = ktx.modes;
	utx->offset = ktx.offset;
	utx->freq = ktx.freq;
	utx->maxerror = ktx.maxerror;
	utx->esterror = ktx.esterror;
	utx->status = ktx.status;
	utx->constant = ktx.constant;
	utx->precision = ktx.precision;
	utx->tolerance = ktx.tolerance;
	utx->time.tv_sec = ktx.time_sec;
	utx->time.tv_usec = ktx.time_usec;
	utx->tick = ktx.tick;
	utx->ppsfreq = ktx.ppsfreq;
	utx->jitter = ktx.jitter;
	utx->shift = ktx.shift;
	utx->stabil = ktx.stabil;
	utx->jitcnt = ktx.jitcnt;
	utx->calcnt = ktx.calcnt;
	utx->errcnt = ktx.errcnt;
	utx->stbcnt = ktx.stbcnt;
	utx->tai = ktx.tai;
	}
	return __syscall_ret(r);
	}
	#ifdef SYS_adjtimex
	if (clock_id==CLOCK_REALTIME) return syscall(SYS_adjtimex, utx);
	#endif
	return syscall(SYS_clock_adjtime, clock_id, utx);
	}