src/pkg/runtime/runtime.c - go - Git at Google

 // Copyright 2009 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 #include "runtime.h"
 #include "arch_GOARCH.h"

 enum {
 	maxround = sizeof(uintptr),
 };

 /*
  * We assume that all architectures turn faults and the like
  * into apparent calls to runtime.sigpanic.  If we see a "call"
  * to runtime.sigpanic, we do not back up the PC to find the
  * line number of the CALL instruction, because there is no CALL.
  */
 void	runtime·sigpanic(void);

 // The GOTRACEBACK environment variable controls the
 // behavior of a Go program that is crashing and exiting.
 //	GOTRACEBACK=0   suppress all tracebacks
 //	GOTRACEBACK=1   default behavior - show tracebacks but exclude runtime frames
 //	GOTRACEBACK=2   show tracebacks including runtime frames
 //	GOTRACEBACK=crash   show tracebacks including runtime frames, then crash (core dump etc)
 int32
 runtime·gotraceback(bool *crash)
 {
 	byte *p;

 	if(crash != nil)
 		*crash = false;
 	p = runtime·getenv("GOTRACEBACK");
 	if(p == nil || p[0] == '\0')
 		return 1;	// default is on
 	if(runtime·strcmp(p, (byte*)"crash") == 0) {
 		if(crash != nil)
 			*crash = true;
 		return 2;	// extra information
 	}
 	return runtime·atoi(p);
 }

 int32
 runtime·mcmp(byte *s1, byte *s2, uintptr n)
 {
 	uintptr i;
 	byte c1, c2;

 	for(i=0; i<n; i++) {
 		c1 = s1[i];
 		c2 = s2[i];
 		if(c1 < c2)
 			return -1;
 		if(c1 > c2)
 			return +1;
 	}
 	return 0;
 }


 byte*
 runtime·mchr(byte *p, byte c, byte *ep)
 {
 	for(; p < ep; p++)
 		if(*p == c)
 			return p;
 	return nil;
 }

 static int32	argc;
 static uint8**	argv;

 Slice os·Args;
 Slice syscall·envs;

 void (*runtime·sysargs)(int32, uint8**);

 void
 runtime·args(int32 c, uint8 **v)
 {
 	argc = c;
 	argv = v;
 	if(runtime·sysargs != nil)
 		runtime·sysargs(c, v);
 }

 int32 runtime·isplan9;
 int32 runtime·iswindows;

 // Information about what cpu features are available.
 // Set on startup in asm_{x86/amd64}.s.
 uint32 runtime·cpuid_ecx;
 uint32 runtime·cpuid_edx;

 void
 runtime·goargs(void)
 {
 	String *s;
 	int32 i;

 	// for windows implementation see "os" package
 	if(Windows)
 		return;

 	s = runtime·malloc(argc*sizeof s[0]);
 	for(i=0; i<argc; i++)
 		s[i] = runtime·gostringnocopy(argv[i]);
 	os·Args.array = (byte*)s;
 	os·Args.len = argc;
 	os·Args.cap = argc;
 }

 void
 runtime·goenvs_unix(void)
 {
 	String *s;
 	int32 i, n;

 	for(n=0; argv[argc+1+n] != 0; n++)
 		;

 	s = runtime·malloc(n*sizeof s[0]);
 	for(i=0; i<n; i++)
 		s[i] = runtime·gostringnocopy(argv[argc+1+i]);
 	syscall·envs.array = (byte*)s;
 	syscall·envs.len = n;
 	syscall·envs.cap = n;
 }

 void
 runtime·getgoroot(String out)
 {
 	byte *p;

 	p = runtime·getenv("GOROOT");
 	out = runtime·gostringnocopy(p);
 	FLUSH(&out);
 }

 int32
 runtime·atoi(byte *p)
 {
 	int32 n;

 	n = 0;
 	while('0' <= *p && *p <= '9')
 		n = n*10 + *p++ - '0';
 	return n;
 }

 static void
 TestAtomic64(void)
 {
 	uint64 z64, x64;

 	z64 = 42;
 	x64 = 0;
 	PREFETCH(&z64);
 	if(runtime·cas64(&z64, &x64, 1))
 		runtime·throw("cas64 failed");
 	if(x64 != 42)
 		runtime·throw("cas64 failed");
 	if(!runtime·cas64(&z64, &x64, 1))
 		runtime·throw("cas64 failed");
 	if(x64 != 42 || z64 != 1)
 		runtime·throw("cas64 failed");
 	if(runtime·atomicload64(&z64) != 1)
 		runtime·throw("load64 failed");
 	runtime·atomicstore64(&z64, (1ull<<40)+1);
 	if(runtime·atomicload64(&z64) != (1ull<<40)+1)
 		runtime·throw("store64 failed");
 	if(runtime·xadd64(&z64, (1ull<<40)+1) != (2ull<<40)+2)
 		runtime·throw("xadd64 failed");
 	if(runtime·atomicload64(&z64) != (2ull<<40)+2)
 		runtime·throw("xadd64 failed");
 	if(runtime·xchg64(&z64, (3ull<<40)+3) != (2ull<<40)+2)
 		runtime·throw("xchg64 failed");
 	if(runtime·atomicload64(&z64) != (3ull<<40)+3)
 		runtime·throw("xchg64 failed");
 }

 void
 runtime·check(void)
 {
 	int8 a;
 	uint8 b;
 	int16 c;
 	uint16 d;
 	int32 e;
 	uint32 f;
 	int64 g;
 	uint64 h;
 	float32 i, i1;
 	float64 j, j1;
 	void* k;
 	uint16* l;
 	struct x1 {
 		byte x;
 	};
 	struct y1 {
 		struct x1 x1;
 		byte y;
 	};

 	if(sizeof(a) != 1) runtime·throw("bad a");
 	if(sizeof(b) != 1) runtime·throw("bad b");
 	if(sizeof(c) != 2) runtime·throw("bad c");
 	if(sizeof(d) != 2) runtime·throw("bad d");
 	if(sizeof(e) != 4) runtime·throw("bad e");
 	if(sizeof(f) != 4) runtime·throw("bad f");
 	if(sizeof(g) != 8) runtime·throw("bad g");
 	if(sizeof(h) != 8) runtime·throw("bad h");
 	if(sizeof(i) != 4) runtime·throw("bad i");
 	if(sizeof(j) != 8) runtime·throw("bad j");
 	if(sizeof(k) != sizeof(uintptr)) runtime·throw("bad k");
 	if(sizeof(l) != sizeof(uintptr)) runtime·throw("bad l");
 	if(sizeof(struct x1) != 1) runtime·throw("bad sizeof x1");
 	if(offsetof(struct y1, y) != 1) runtime·throw("bad offsetof y1.y");
 	if(sizeof(struct y1) != 2) runtime·throw("bad sizeof y1");

 	uint32 z;
 	z = 1;
 	if(!runtime·cas(&z, 1, 2))
 		runtime·throw("cas1");
 	if(z != 2)
 		runtime·throw("cas2");

 	z = 4;
 	if(runtime·cas(&z, 5, 6))
 		runtime·throw("cas3");
 	if(z != 4)
 		runtime·throw("cas4");

 	*(uint64*)&j = ~0ULL;
 	if(j == j)
 		runtime·throw("float64nan");
 	if(!(j != j))
 		runtime·throw("float64nan1");

 	*(uint64*)&j1 = ~1ULL;
 	if(j == j1)
 		runtime·throw("float64nan2");
 	if(!(j != j1))
 		runtime·throw("float64nan3");

 	*(uint32*)&i = ~0UL;
 	if(i == i)
 		runtime·throw("float32nan");
 	if(!(i != i))
 		runtime·throw("float32nan1");

 	*(uint32*)&i1 = ~1UL;
 	if(i == i1)
 		runtime·throw("float32nan2");
 	if(!(i != i1))
 		runtime·throw("float32nan3");

 	TestAtomic64();
 }

 void
 runtime·Caller(intgo skip, uintptr retpc, String retfile, intgo retline, bool retbool)
 {
 	Func *f, *g;
 	uintptr pc;
 	uintptr rpc[2];

 	/*
 	 * Ask for two PCs: the one we were asked for
 	 * and what it called, so that we can see if it
 	 * "called" sigpanic.
 	 */
 	retpc = 0;
 	if(runtime·callers(1+skip-1, rpc, 2) < 2) {
 		retfile = runtime·emptystring;
 		retline = 0;
 		retbool = false;
 	} else if((f = runtime·findfunc(rpc[1])) == nil) {
 		retfile = runtime·emptystring;
 		retline = 0;
 		retbool = true;  // have retpc at least
 	} else {
 		retpc = rpc[1];
 		retfile = f->src;
 		pc = retpc;
 		g = runtime·findfunc(rpc[0]);
 		if(pc > f->entry && (g == nil || g->entry != (uintptr)runtime·sigpanic))
 			pc--;
 		retline = runtime·funcline(f, pc);
 		retbool = true;
 	}
 	FLUSH(&retpc);
 	FLUSH(&retfile);
 	FLUSH(&retline);
 	FLUSH(&retbool);
 }

 void
 runtime·Callers(intgo skip, Slice pc, intgo retn)
 {
 	// runtime.callers uses pc.array==nil as a signal
 	// to print a stack trace.  Pick off 0-length pc here
 	// so that we don't let a nil pc slice get to it.
 	if(pc.len == 0)
 		retn = 0;
 	else
 		retn = runtime·callers(skip, (uintptr*)pc.array, pc.len);
 	FLUSH(&retn);
 }

 void
 runtime·FuncForPC(uintptr pc, void *retf)
 {
 	retf = runtime·findfunc(pc);
 	FLUSH(&retf);
 }

 uint32
 runtime·fastrand1(void)
 {
 	uint32 x;

 	x = m->fastrand;
 	x += x;
 	if(x & 0x80000000L)
 		x ^= 0x88888eefUL;
 	m->fastrand = x;
 	return x;
 }

 static Lock ticksLock;
 static int64 ticks;

 int64
 runtime·tickspersecond(void)
 {
 	int64 res, t0, t1, c0, c1;

 	res = (int64)runtime·atomicload64((uint64*)&ticks);
 	if(res != 0)
 		return ticks;
 	runtime·lock(&ticksLock);
 	res = ticks;
 	if(res == 0) {
 		t0 = runtime·nanotime();
 		c0 = runtime·cputicks();
 		runtime·usleep(100*1000);
 		t1 = runtime·nanotime();
 		c1 = runtime·cputicks();
 		if(t1 == t0)
 			t1++;
 		res = (c1-c0)*1000*1000*1000/(t1-t0);
 		if(res == 0)
 			res++;
 		runtime·atomicstore64((uint64*)&ticks, res);
 	}
 	runtime·unlock(&ticksLock);
 	return res;
 }

 void
 runtime∕pprof·runtime_cyclesPerSecond(int64 res)
 {
 	res = runtime·tickspersecond();
 	FLUSH(&res);
 }
	// Copyright 2009 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	#include "runtime.h"
	#include "arch_GOARCH.h"

	enum {
	maxround = sizeof(uintptr),
	};

	/*
	* We assume that all architectures turn faults and the like
	* into apparent calls to runtime.sigpanic. If we see a "call"
	* to runtime.sigpanic, we do not back up the PC to find the
	* line number of the CALL instruction, because there is no CALL.
	*/
	void runtime·sigpanic(void);

	// The GOTRACEBACK environment variable controls the
	// behavior of a Go program that is crashing and exiting.
	// GOTRACEBACK=0 suppress all tracebacks
	// GOTRACEBACK=1 default behavior - show tracebacks but exclude runtime frames
	// GOTRACEBACK=2 show tracebacks including runtime frames
	// GOTRACEBACK=crash show tracebacks including runtime frames, then crash (core dump etc)
	int32
	runtime·gotraceback(bool *crash)
	{
	byte *p;

	if(crash != nil)
	*crash = false;
	p = runtime·getenv("GOTRACEBACK");
	if(p == nil \|\| p[0] == '\0')
	return 1; // default is on
	if(runtime·strcmp(p, (byte*)"crash") == 0) {
	if(crash != nil)
	*crash = true;
	return 2; // extra information
	}
	return runtime·atoi(p);
	}

	int32
	runtime·mcmp(byte s1, byte s2, uintptr n)
	{
	uintptr i;
	byte c1, c2;

	for(i=0; i<n; i++) {
	c1 = s1[i];
	c2 = s2[i];
	if(c1 < c2)
	return -1;
	if(c1 > c2)
	return +1;
	}
	return 0;
	}


	byte*
	runtime·mchr(byte p, byte c, byte ep)
	{
	for(; p < ep; p++)
	if(*p == c)
	return p;
	return nil;
	}

	static int32 argc;
	static uint8** argv;

	Slice os·Args;
	Slice syscall·envs;

	void (runtime·sysargs)(int32, uint8*);

	void
	runtime·args(int32 c, uint8 **v)
	{
	argc = c;
	argv = v;
	if(runtime·sysargs != nil)
	runtime·sysargs(c, v);
	}

	int32 runtime·isplan9;
	int32 runtime·iswindows;

	// Information about what cpu features are available.
	// Set on startup in asm_{x86/amd64}.s.
	uint32 runtime·cpuid_ecx;
	uint32 runtime·cpuid_edx;

	void
	runtime·goargs(void)
	{
	String *s;
	int32 i;

	// for windows implementation see "os" package
	if(Windows)
	return;

	s = runtime·malloc(argc*sizeof s[0]);
	for(i=0; i<argc; i++)
	s[i] = runtime·gostringnocopy(argv[i]);
	os·Args.array = (byte*)s;
	os·Args.len = argc;
	os·Args.cap = argc;
	}

	void
	runtime·goenvs_unix(void)
	{
	String *s;
	int32 i, n;

	for(n=0; argv[argc+1+n] != 0; n++)
	;

	s = runtime·malloc(n*sizeof s[0]);
	for(i=0; i<n; i++)
	s[i] = runtime·gostringnocopy(argv[argc+1+i]);
	syscall·envs.array = (byte*)s;
	syscall·envs.len = n;
	syscall·envs.cap = n;
	}

	void
	runtime·getgoroot(String out)
	{
	byte *p;

	p = runtime·getenv("GOROOT");
	out = runtime·gostringnocopy(p);
	FLUSH(&out);
	}

	int32
	runtime·atoi(byte *p)
	{
	int32 n;

	n = 0;
	while('0' <= p && p <= '9')
	n = n10 + p++ - '0';
	return n;
	}

	static void
	TestAtomic64(void)
	{
	uint64 z64, x64;

	z64 = 42;
	x64 = 0;
	PREFETCH(&z64);
	if(runtime·cas64(&z64, &x64, 1))
	runtime·throw("cas64 failed");
	if(x64 != 42)
	runtime·throw("cas64 failed");
	if(!runtime·cas64(&z64, &x64, 1))
	runtime·throw("cas64 failed");
	if(x64 != 42 \|\| z64 != 1)
	runtime·throw("cas64 failed");
	if(runtime·atomicload64(&z64) != 1)
	runtime·throw("load64 failed");
	runtime·atomicstore64(&z64, (1ull<<40)+1);
	if(runtime·atomicload64(&z64) != (1ull<<40)+1)
	runtime·throw("store64 failed");
	if(runtime·xadd64(&z64, (1ull<<40)+1) != (2ull<<40)+2)
	runtime·throw("xadd64 failed");
	if(runtime·atomicload64(&z64) != (2ull<<40)+2)
	runtime·throw("xadd64 failed");
	if(runtime·xchg64(&z64, (3ull<<40)+3) != (2ull<<40)+2)
	runtime·throw("xchg64 failed");
	if(runtime·atomicload64(&z64) != (3ull<<40)+3)
	runtime·throw("xchg64 failed");
	}

	void
	runtime·check(void)
	{
	int8 a;
	uint8 b;
	int16 c;
	uint16 d;
	int32 e;
	uint32 f;
	int64 g;
	uint64 h;
	float32 i, i1;
	float64 j, j1;
	void* k;
	uint16* l;
	struct x1 {
	byte x;
	};
	struct y1 {
	struct x1 x1;
	byte y;
	};

	if(sizeof(a) != 1) runtime·throw("bad a");
	if(sizeof(b) != 1) runtime·throw("bad b");
	if(sizeof(c) != 2) runtime·throw("bad c");
	if(sizeof(d) != 2) runtime·throw("bad d");
	if(sizeof(e) != 4) runtime·throw("bad e");
	if(sizeof(f) != 4) runtime·throw("bad f");
	if(sizeof(g) != 8) runtime·throw("bad g");
	if(sizeof(h) != 8) runtime·throw("bad h");
	if(sizeof(i) != 4) runtime·throw("bad i");
	if(sizeof(j) != 8) runtime·throw("bad j");
	if(sizeof(k) != sizeof(uintptr)) runtime·throw("bad k");
	if(sizeof(l) != sizeof(uintptr)) runtime·throw("bad l");
	if(sizeof(struct x1) != 1) runtime·throw("bad sizeof x1");
	if(offsetof(struct y1, y) != 1) runtime·throw("bad offsetof y1.y");
	if(sizeof(struct y1) != 2) runtime·throw("bad sizeof y1");

	uint32 z;
	z = 1;
	if(!runtime·cas(&z, 1, 2))
	runtime·throw("cas1");
	if(z != 2)
	runtime·throw("cas2");

	z = 4;
	if(runtime·cas(&z, 5, 6))
	runtime·throw("cas3");
	if(z != 4)
	runtime·throw("cas4");

	(uint64)&j = ~0ULL;
	if(j == j)
	runtime·throw("float64nan");
	if(!(j != j))
	runtime·throw("float64nan1");

	(uint64)&j1 = ~1ULL;
	if(j == j1)
	runtime·throw("float64nan2");
	if(!(j != j1))
	runtime·throw("float64nan3");

	(uint32)&i = ~0UL;
	if(i == i)
	runtime·throw("float32nan");
	if(!(i != i))
	runtime·throw("float32nan1");

	(uint32)&i1 = ~1UL;
	if(i == i1)
	runtime·throw("float32nan2");
	if(!(i != i1))
	runtime·throw("float32nan3");

	TestAtomic64();
	}

	void
	runtime·Caller(intgo skip, uintptr retpc, String retfile, intgo retline, bool retbool)
	{
	Func f, g;
	uintptr pc;
	uintptr rpc[2];

	/*
	* Ask for two PCs: the one we were asked for
	* and what it called, so that we can see if it
	* "called" sigpanic.
	*/
	retpc = 0;
	if(runtime·callers(1+skip-1, rpc, 2) < 2) {
	retfile = runtime·emptystring;
	retline = 0;
	retbool = false;
	} else if((f = runtime·findfunc(rpc[1])) == nil) {
	retfile = runtime·emptystring;
	retline = 0;
	retbool = true; // have retpc at least
	} else {
	retpc = rpc[1];
	retfile = f->src;
	pc = retpc;
	g = runtime·findfunc(rpc[0]);
	if(pc > f->entry && (g == nil \|\| g->entry != (uintptr)runtime·sigpanic))
	pc--;
	retline = runtime·funcline(f, pc);
	retbool = true;
	}
	FLUSH(&retpc);
	FLUSH(&retfile);
	FLUSH(&retline);
	FLUSH(&retbool);
	}

	void
	runtime·Callers(intgo skip, Slice pc, intgo retn)
	{
	// runtime.callers uses pc.array==nil as a signal
	// to print a stack trace. Pick off 0-length pc here
	// so that we don't let a nil pc slice get to it.
	if(pc.len == 0)
	retn = 0;
	else
	retn = runtime·callers(skip, (uintptr*)pc.array, pc.len);
	FLUSH(&retn);
	}

	void
	runtime·FuncForPC(uintptr pc, void *retf)
	{
	retf = runtime·findfunc(pc);
	FLUSH(&retf);
	}

	uint32
	runtime·fastrand1(void)
	{
	uint32 x;

	x = m->fastrand;
	x += x;
	if(x & 0x80000000L)
	x ^= 0x88888eefUL;
	m->fastrand = x;
	return x;
	}

	static Lock ticksLock;
	static int64 ticks;

	int64
	runtime·tickspersecond(void)
	{
	int64 res, t0, t1, c0, c1;

	res = (int64)runtime·atomicload64((uint64*)&ticks);
	if(res != 0)
	return ticks;
	runtime·lock(&ticksLock);
	res = ticks;
	if(res == 0) {
	t0 = runtime·nanotime();
	c0 = runtime·cputicks();
	runtime·usleep(100*1000);
	t1 = runtime·nanotime();
	c1 = runtime·cputicks();
	if(t1 == t0)
	t1++;
	res = (c1-c0)10001000*1000/(t1-t0);
	if(res == 0)
	res++;
	runtime·atomicstore64((uint64*)&ticks, res);
	}
	runtime·unlock(&ticksLock);
	return res;
	}

	void
	runtime∕pprof·runtime_cyclesPerSecond(int64 res)
	{
	res = runtime·tickspersecond();
	FLUSH(&res);
	}