gcc/libgo/runtime/runtime.h
Ian Lance Taylor dffa732835 reflect, runtime: Use libffi closures to implement reflect.MakeFunc.
Keep using the existing 386 and amd64 code on those archs,
since it is more efficient.

From-SVN: r212853
2014-07-19 21:36:26 +00:00

853 lines
24 KiB
C

// 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 "config.h"
#include "go-assert.h"
#include <complex.h>
#include <signal.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include <pthread.h>
#include <semaphore.h>
#include <ucontext.h>
#ifdef HAVE_SYS_MMAN_H
#include <sys/mman.h>
#endif
#include "interface.h"
#include "go-alloc.h"
#define _STRINGIFY2_(x) #x
#define _STRINGIFY_(x) _STRINGIFY2_(x)
#define GOSYM_PREFIX _STRINGIFY_(__USER_LABEL_PREFIX__)
/* This file supports C files copied from the 6g runtime library.
This is a version of the 6g runtime.h rewritten for gccgo's version
of the code. */
typedef signed int int8 __attribute__ ((mode (QI)));
typedef unsigned int uint8 __attribute__ ((mode (QI)));
typedef signed int int16 __attribute__ ((mode (HI)));
typedef unsigned int uint16 __attribute__ ((mode (HI)));
typedef signed int int32 __attribute__ ((mode (SI)));
typedef unsigned int uint32 __attribute__ ((mode (SI)));
typedef signed int int64 __attribute__ ((mode (DI)));
typedef unsigned int uint64 __attribute__ ((mode (DI)));
typedef float float32 __attribute__ ((mode (SF)));
typedef double float64 __attribute__ ((mode (DF)));
typedef signed int intptr __attribute__ ((mode (pointer)));
typedef unsigned int uintptr __attribute__ ((mode (pointer)));
typedef intptr intgo; // Go's int
typedef uintptr uintgo; // Go's uint
typedef uintptr uintreg;
/* Defined types. */
typedef uint8 bool;
typedef uint8 byte;
typedef struct Func Func;
typedef struct G G;
typedef struct Lock Lock;
typedef struct M M;
typedef struct P P;
typedef struct Note Note;
typedef struct String String;
typedef struct FuncVal FuncVal;
typedef struct SigTab SigTab;
typedef struct MCache MCache;
typedef struct FixAlloc FixAlloc;
typedef struct Hchan Hchan;
typedef struct Timers Timers;
typedef struct Timer Timer;
typedef struct GCStats GCStats;
typedef struct LFNode LFNode;
typedef struct ParFor ParFor;
typedef struct ParForThread ParForThread;
typedef struct CgoMal CgoMal;
typedef struct PollDesc PollDesc;
typedef struct DebugVars DebugVars;
typedef struct __go_open_array Slice;
typedef struct __go_interface Iface;
typedef struct __go_empty_interface Eface;
typedef struct __go_type_descriptor Type;
typedef struct __go_defer_stack Defer;
typedef struct __go_panic_stack Panic;
typedef struct __go_ptr_type PtrType;
typedef struct __go_func_type FuncType;
typedef struct __go_interface_type InterfaceType;
typedef struct __go_map_type MapType;
typedef struct __go_channel_type ChanType;
typedef struct Traceback Traceback;
typedef struct Location Location;
/*
* Per-CPU declaration.
*/
extern M* runtime_m(void);
extern G* runtime_g(void);
extern M runtime_m0;
extern G runtime_g0;
/*
* defined constants
*/
enum
{
// G status
//
// If you add to this list, add to the list
// of "okay during garbage collection" status
// in mgc0.c too.
Gidle,
Grunnable,
Grunning,
Gsyscall,
Gwaiting,
Gmoribund_unused, // currently unused, but hardcoded in gdb scripts
Gdead,
};
enum
{
// P status
Pidle,
Prunning,
Psyscall,
Pgcstop,
Pdead,
};
enum
{
true = 1,
false = 0,
};
enum
{
PtrSize = sizeof(void*),
};
enum
{
// Per-M stack segment cache size.
StackCacheSize = 32,
// Global <-> per-M stack segment cache transfer batch size.
StackCacheBatch = 16,
};
/*
* structures
*/
struct Lock
{
// Futex-based impl treats it as uint32 key,
// while sema-based impl as M* waitm.
// Used to be a union, but unions break precise GC.
uintptr key;
};
struct Note
{
// Futex-based impl treats it as uint32 key,
// while sema-based impl as M* waitm.
// Used to be a union, but unions break precise GC.
uintptr key;
};
struct String
{
const byte* str;
intgo len;
};
struct FuncVal
{
void (*fn)(void);
// variable-size, fn-specific data here
};
struct GCStats
{
// the struct must consist of only uint64's,
// because it is casted to uint64[].
uint64 nhandoff;
uint64 nhandoffcnt;
uint64 nprocyield;
uint64 nosyield;
uint64 nsleep;
};
// A location in the program, used for backtraces.
struct Location
{
uintptr pc;
String filename;
String function;
intgo lineno;
};
struct G
{
void* closure; // Closure value.
Defer* defer;
Panic* panic;
void* exception; // current exception being thrown
bool is_foreign; // whether current exception from other language
void *gcstack; // if status==Gsyscall, gcstack = stackbase to use during gc
uintptr gcstack_size;
void* gcnext_segment;
void* gcnext_sp;
void* gcinitial_sp;
ucontext_t gcregs;
byte* entry; // initial function
void* param; // passed parameter on wakeup
bool fromgogo; // reached from gogo
int16 status;
uint32 selgen; // valid sudog pointer
int64 goid;
int64 waitsince; // approx time when the G become blocked
const char* waitreason; // if status==Gwaiting
G* schedlink;
bool ispanic;
bool issystem; // do not output in stack dump
bool isbackground; // ignore in deadlock detector
bool paniconfault; // panic (instead of crash) on unexpected fault address
M* m; // for debuggers, but offset not hard-coded
M* lockedm;
int32 sig;
int32 writenbuf;
byte* writebuf;
uintptr sigcode0;
uintptr sigcode1;
// uintptr sigpc;
uintptr gopc; // pc of go statement that created this goroutine
int32 ncgo;
CgoMal* cgomal;
Traceback* traceback;
ucontext_t context;
void* stack_context[10];
};
struct M
{
G* g0; // goroutine with scheduling stack
G* gsignal; // signal-handling G
byte* gsignalstack;
size_t gsignalstacksize;
void (*mstartfn)(void);
G* curg; // current running goroutine
G* caughtsig; // goroutine running during fatal signal
P* p; // attached P for executing Go code (nil if not executing Go code)
P* nextp;
int32 id;
int32 mallocing;
int32 throwing;
int32 gcing;
int32 locks;
int32 softfloat;
int32 dying;
int32 profilehz;
int32 helpgc;
bool spinning; // M is out of work and is actively looking for work
bool blocked; // M is blocked on a Note
uint32 fastrand;
uint64 ncgocall; // number of cgo calls in total
int32 ncgo; // number of cgo calls currently in progress
CgoMal* cgomal;
Note park;
M* alllink; // on allm
M* schedlink;
MCache *mcache;
G* lockedg;
Location createstack[32]; // Stack that created this thread.
uint32 locked; // tracking for LockOSThread
M* nextwaitm; // next M waiting for lock
uintptr waitsema; // semaphore for parking on locks
uint32 waitsemacount;
uint32 waitsemalock;
GCStats gcstats;
bool needextram;
bool dropextram; // for gccgo: drop after call is done.
uint8 traceback;
bool (*waitunlockf)(G*, void*);
void* waitlock;
uintptr end[];
};
struct P
{
Lock;
int32 id;
uint32 status; // one of Pidle/Prunning/...
P* link;
uint32 schedtick; // incremented on every scheduler call
uint32 syscalltick; // incremented on every system call
M* m; // back-link to associated M (nil if idle)
MCache* mcache;
Defer* deferpool; // pool of available Defer structs (see panic.c)
// Cache of goroutine ids, amortizes accesses to runtime_sched.goidgen.
uint64 goidcache;
uint64 goidcacheend;
// Queue of runnable goroutines.
uint32 runqhead;
uint32 runqtail;
G* runq[256];
// Available G's (status == Gdead)
G* gfree;
int32 gfreecnt;
byte pad[64];
};
// The m->locked word holds two pieces of state counting active calls to LockOSThread/lockOSThread.
// The low bit (LockExternal) is a boolean reporting whether any LockOSThread call is active.
// External locks are not recursive; a second lock is silently ignored.
// The upper bits of m->lockedcount record the nesting depth of calls to lockOSThread
// (counting up by LockInternal), popped by unlockOSThread (counting down by LockInternal).
// Internal locks can be recursive. For instance, a lock for cgo can occur while the main
// goroutine is holding the lock during the initialization phase.
enum
{
LockExternal = 1,
LockInternal = 2,
};
struct SigTab
{
int32 sig;
int32 flags;
};
enum
{
SigNotify = 1<<0, // let signal.Notify have signal, even if from kernel
SigKill = 1<<1, // if signal.Notify doesn't take it, exit quietly
SigThrow = 1<<2, // if signal.Notify doesn't take it, exit loudly
SigPanic = 1<<3, // if the signal is from the kernel, panic
SigDefault = 1<<4, // if the signal isn't explicitly requested, don't monitor it
SigHandling = 1<<5, // our signal handler is registered
SigIgnored = 1<<6, // the signal was ignored before we registered for it
SigGoExit = 1<<7, // cause all runtime procs to exit (only used on Plan 9).
};
// Layout of in-memory per-function information prepared by linker
// See http://golang.org/s/go12symtab.
// Keep in sync with linker and with ../../libmach/sym.c
// and with package debug/gosym.
struct Func
{
String name;
uintptr entry; // entry pc
};
#ifdef GOOS_nacl
enum {
NaCl = 1,
};
#else
enum {
NaCl = 0,
};
#endif
#ifdef GOOS_windows
enum {
Windows = 1
};
#else
enum {
Windows = 0
};
#endif
#ifdef GOOS_solaris
enum {
Solaris = 1
};
#else
enum {
Solaris = 0
};
#endif
struct Timers
{
Lock;
G *timerproc;
bool sleeping;
bool rescheduling;
Note waitnote;
Timer **t;
int32 len;
int32 cap;
};
// Package time knows the layout of this structure.
// If this struct changes, adjust ../time/sleep.go:/runtimeTimer.
// For GOOS=nacl, package syscall knows the layout of this structure.
// If this struct changes, adjust ../syscall/net_nacl.go:/runtimeTimer.
struct Timer
{
int32 i; // heap index
// Timer wakes up at when, and then at when+period, ... (period > 0 only)
// each time calling f(now, arg) in the timer goroutine, so f must be
// a well-behaved function and not block.
int64 when;
int64 period;
FuncVal *fv;
Eface arg;
};
// Lock-free stack node.
struct LFNode
{
LFNode *next;
uintptr pushcnt;
};
// Parallel for descriptor.
struct ParFor
{
void (*body)(ParFor*, uint32); // executed for each element
uint32 done; // number of idle threads
uint32 nthr; // total number of threads
uint32 nthrmax; // maximum number of threads
uint32 thrseq; // thread id sequencer
uint32 cnt; // iteration space [0, cnt)
void *ctx; // arbitrary user context
bool wait; // if true, wait while all threads finish processing,
// otherwise parfor may return while other threads are still working
ParForThread *thr; // array of thread descriptors
uint32 pad; // to align ParForThread.pos for 64-bit atomic operations
// stats
uint64 nsteal;
uint64 nstealcnt;
uint64 nprocyield;
uint64 nosyield;
uint64 nsleep;
};
// Track memory allocated by code not written in Go during a cgo call,
// so that the garbage collector can see them.
struct CgoMal
{
CgoMal *next;
void *alloc;
};
// Holds variables parsed from GODEBUG env var.
struct DebugVars
{
int32 allocfreetrace;
int32 efence;
int32 gctrace;
int32 gcdead;
int32 scheddetail;
int32 schedtrace;
};
extern bool runtime_precisestack;
extern bool runtime_copystack;
/*
* defined macros
* you need super-gopher-guru privilege
* to add this list.
*/
#define nelem(x) (sizeof(x)/sizeof((x)[0]))
#define nil ((void*)0)
#define USED(v) ((void) v)
#define ROUND(x, n) (((x)+(n)-1)&~(uintptr)((n)-1)) /* all-caps to mark as macro: it evaluates n twice */
byte* runtime_startup_random_data;
uint32 runtime_startup_random_data_len;
void runtime_get_random_data(byte**, int32*);
enum {
// hashinit wants this many random bytes
HashRandomBytes = 32
};
void runtime_hashinit(void);
void runtime_traceback(void);
void runtime_tracebackothers(G*);
enum
{
// The maximum number of frames we print for a traceback
TracebackMaxFrames = 100,
};
/*
* external data
*/
extern uintptr runtime_zerobase;
extern G** runtime_allg;
extern uintptr runtime_allglen;
extern G* runtime_lastg;
extern M* runtime_allm;
extern P** runtime_allp;
extern int32 runtime_gomaxprocs;
extern uint32 runtime_needextram;
extern uint32 runtime_panicking;
extern int8* runtime_goos;
extern int32 runtime_ncpu;
extern void (*runtime_sysargs)(int32, uint8**);
extern uint32 runtime_Hchansize;
extern DebugVars runtime_debug;
extern uintptr runtime_maxstacksize;
/*
* common functions and data
*/
#define runtime_strcmp(s1, s2) __builtin_strcmp((s1), (s2))
#define runtime_strncmp(s1, s2, n) __builtin_strncmp((s1), (s2), (n))
#define runtime_strstr(s1, s2) __builtin_strstr((s1), (s2))
intgo runtime_findnull(const byte*);
intgo runtime_findnullw(const uint16*);
void runtime_dump(byte*, int32);
void runtime_gogo(G*);
struct __go_func_type;
void runtime_args(int32, byte**);
void runtime_osinit();
void runtime_goargs(void);
void runtime_goenvs(void);
void runtime_goenvs_unix(void);
void runtime_throw(const char*) __attribute__ ((noreturn));
void runtime_panicstring(const char*) __attribute__ ((noreturn));
bool runtime_canpanic(G*);
void runtime_prints(const char*);
void runtime_printf(const char*, ...);
int32 runtime_snprintf(byte*, int32, const char*, ...);
#define runtime_mcmp(a, b, s) __builtin_memcmp((a), (b), (s))
#define runtime_memmove(a, b, s) __builtin_memmove((a), (b), (s))
void* runtime_mal(uintptr);
String runtime_gostring(const byte*);
String runtime_gostringnocopy(const byte*);
void runtime_schedinit(void);
void runtime_initsig(void);
void runtime_sigenable(uint32 sig);
void runtime_sigdisable(uint32 sig);
int32 runtime_gotraceback(bool *crash);
void runtime_goroutineheader(G*);
void runtime_printtrace(Location*, int32, bool);
#define runtime_open(p, f, m) open((p), (f), (m))
#define runtime_read(d, v, n) read((d), (v), (n))
#define runtime_write(d, v, n) write((d), (v), (n))
#define runtime_close(d) close(d)
void runtime_ready(G*);
const byte* runtime_getenv(const char*);
int32 runtime_atoi(const byte*);
void* runtime_mstart(void*);
G* runtime_malg(int32, byte**, size_t*);
void runtime_mpreinit(M*);
void runtime_minit(void);
void runtime_unminit(void);
void runtime_needm(void);
void runtime_dropm(void);
void runtime_signalstack(byte*, int32);
MCache* runtime_allocmcache(void);
void runtime_freemcache(MCache*);
void runtime_mallocinit(void);
void runtime_mprofinit(void);
#define runtime_malloc(s) __go_alloc(s)
#define runtime_free(p) __go_free(p)
#define runtime_getcallersp(p) __builtin_frame_address(1)
int32 runtime_mcount(void);
int32 runtime_gcount(void);
void runtime_mcall(void(*)(G*));
uint32 runtime_fastrand1(void);
int32 runtime_timediv(int64, int32, int32*);
int32 runtime_round2(int32 x); // round x up to a power of 2.
// atomic operations
#define runtime_cas(pval, old, new) __sync_bool_compare_and_swap (pval, old, new)
#define runtime_cas64(pval, old, new) __sync_bool_compare_and_swap (pval, old, new)
#define runtime_casp(pval, old, new) __sync_bool_compare_and_swap (pval, old, new)
// Don't confuse with XADD x86 instruction,
// this one is actually 'addx', that is, add-and-fetch.
#define runtime_xadd(p, v) __sync_add_and_fetch (p, v)
#define runtime_xadd64(p, v) __sync_add_and_fetch (p, v)
#define runtime_xchg(p, v) __atomic_exchange_n (p, v, __ATOMIC_SEQ_CST)
#define runtime_xchg64(p, v) __atomic_exchange_n (p, v, __ATOMIC_SEQ_CST)
#define runtime_xchgp(p, v) __atomic_exchange_n (p, v, __ATOMIC_SEQ_CST)
#define runtime_atomicload(p) __atomic_load_n (p, __ATOMIC_SEQ_CST)
#define runtime_atomicstore(p, v) __atomic_store_n (p, v, __ATOMIC_SEQ_CST)
#define runtime_atomicstore64(p, v) __atomic_store_n (p, v, __ATOMIC_SEQ_CST)
#define runtime_atomicload64(p) __atomic_load_n (p, __ATOMIC_SEQ_CST)
#define runtime_atomicloadp(p) __atomic_load_n (p, __ATOMIC_SEQ_CST)
#define runtime_atomicstorep(p, v) __atomic_store_n (p, v, __ATOMIC_SEQ_CST)
void runtime_setmg(M*, G*);
void runtime_newextram(void);
#define runtime_exit(s) exit(s)
#define runtime_breakpoint() __builtin_trap()
void runtime_gosched(void);
void runtime_gosched0(G*);
void runtime_schedtrace(bool);
void runtime_park(bool(*)(G*, void*), void*, const char*);
void runtime_parkunlock(Lock*, const char*);
void runtime_tsleep(int64, const char*);
M* runtime_newm(void);
void runtime_goexit(void);
void runtime_entersyscall(void) __asm__ (GOSYM_PREFIX "syscall.Entersyscall");
void runtime_entersyscallblock(void);
void runtime_exitsyscall(void) __asm__ (GOSYM_PREFIX "syscall.Exitsyscall");
G* __go_go(void (*pfn)(void*), void*);
void siginit(void);
bool __go_sigsend(int32 sig);
int32 runtime_callers(int32, Location*, int32, bool keep_callers);
int64 runtime_nanotime(void); // monotonic time
int64 runtime_unixnanotime(void); // real time, can skip
void runtime_dopanic(int32) __attribute__ ((noreturn));
void runtime_startpanic(void);
void runtime_freezetheworld(void);
void runtime_unwindstack(G*, byte*);
void runtime_sigprof();
void runtime_resetcpuprofiler(int32);
void runtime_setcpuprofilerate(void(*)(uintptr*, int32), int32);
void runtime_usleep(uint32);
int64 runtime_cputicks(void);
int64 runtime_tickspersecond(void);
void runtime_blockevent(int64, int32);
extern int64 runtime_blockprofilerate;
void runtime_addtimer(Timer*);
bool runtime_deltimer(Timer*);
G* runtime_netpoll(bool);
void runtime_netpollinit(void);
int32 runtime_netpollopen(uintptr, PollDesc*);
int32 runtime_netpollclose(uintptr);
void runtime_netpollready(G**, PollDesc*, int32);
uintptr runtime_netpollfd(PollDesc*);
void runtime_netpollarm(PollDesc*, int32);
void** runtime_netpolluser(PollDesc*);
bool runtime_netpollclosing(PollDesc*);
void runtime_netpolllock(PollDesc*);
void runtime_netpollunlock(PollDesc*);
void runtime_crash(void);
void runtime_parsedebugvars(void);
void _rt0_go(void);
void* runtime_funcdata(Func*, int32);
int32 runtime_setmaxthreads(int32);
G* runtime_timejump(void);
void runtime_iterate_finq(void (*callback)(FuncVal*, void*, const FuncType*, const PtrType*));
void runtime_stoptheworld(void);
void runtime_starttheworld(void);
extern uint32 runtime_worldsema;
/*
* mutual exclusion locks. in the uncontended case,
* as fast as spin locks (just a few user-level instructions),
* but on the contention path they sleep in the kernel.
* a zeroed Lock is unlocked (no need to initialize each lock).
*/
void runtime_lock(Lock*);
void runtime_unlock(Lock*);
/*
* sleep and wakeup on one-time events.
* before any calls to notesleep or notewakeup,
* must call noteclear to initialize the Note.
* then, exactly one thread can call notesleep
* and exactly one thread can call notewakeup (once).
* once notewakeup has been called, the notesleep
* will return. future notesleep will return immediately.
* subsequent noteclear must be called only after
* previous notesleep has returned, e.g. it's disallowed
* to call noteclear straight after notewakeup.
*
* notetsleep is like notesleep but wakes up after
* a given number of nanoseconds even if the event
* has not yet happened. if a goroutine uses notetsleep to
* wake up early, it must wait to call noteclear until it
* can be sure that no other goroutine is calling
* notewakeup.
*
* notesleep/notetsleep are generally called on g0,
* notetsleepg is similar to notetsleep but is called on user g.
*/
void runtime_noteclear(Note*);
void runtime_notesleep(Note*);
void runtime_notewakeup(Note*);
bool runtime_notetsleep(Note*, int64); // false - timeout
bool runtime_notetsleepg(Note*, int64); // false - timeout
/*
* low-level synchronization for implementing the above
*/
uintptr runtime_semacreate(void);
int32 runtime_semasleep(int64);
void runtime_semawakeup(M*);
// or
void runtime_futexsleep(uint32*, uint32, int64);
void runtime_futexwakeup(uint32*, uint32);
/*
* Lock-free stack.
* Initialize uint64 head to 0, compare with 0 to test for emptiness.
* The stack does not keep pointers to nodes,
* so they can be garbage collected if there are no other pointers to nodes.
*/
void runtime_lfstackpush(uint64 *head, LFNode *node)
__asm__ (GOSYM_PREFIX "runtime.lfstackpush");
LFNode* runtime_lfstackpop(uint64 *head);
/*
* Parallel for over [0, n).
* body() is executed for each iteration.
* nthr - total number of worker threads.
* ctx - arbitrary user context.
* if wait=true, threads return from parfor() when all work is done;
* otherwise, threads can return while other threads are still finishing processing.
*/
ParFor* runtime_parforalloc(uint32 nthrmax);
void runtime_parforsetup(ParFor *desc, uint32 nthr, uint32 n, void *ctx, bool wait, void (*body)(ParFor*, uint32));
void runtime_parfordo(ParFor *desc);
void runtime_parforiters(ParFor*, uintptr, uintptr*, uintptr*);
/*
* low level C-called
*/
#define runtime_mmap mmap
#define runtime_munmap munmap
#define runtime_madvise madvise
#define runtime_memclr(buf, size) __builtin_memset((buf), 0, (size))
#define runtime_getcallerpc(p) __builtin_return_address(0)
#ifdef __rtems__
void __wrap_rtems_task_variable_add(void **);
#endif
/*
* Names generated by gccgo.
*/
#define runtime_printbool __go_print_bool
#define runtime_printfloat __go_print_double
#define runtime_printint __go_print_int64
#define runtime_printiface __go_print_interface
#define runtime_printeface __go_print_empty_interface
#define runtime_printstring __go_print_string
#define runtime_printpointer __go_print_pointer
#define runtime_printuint __go_print_uint64
#define runtime_printslice __go_print_slice
#define runtime_printcomplex __go_print_complex
/*
* runtime go-called
*/
void runtime_printbool(_Bool);
void runtime_printbyte(int8);
void runtime_printfloat(double);
void runtime_printint(int64);
void runtime_printiface(Iface);
void runtime_printeface(Eface);
void runtime_printstring(String);
void runtime_printpc(void*);
void runtime_printpointer(void*);
void runtime_printuint(uint64);
void runtime_printhex(uint64);
void runtime_printslice(Slice);
void runtime_printcomplex(complex double);
void reflect_call(const struct __go_func_type *, FuncVal *, _Bool, _Bool,
void **, void **)
__asm__ (GOSYM_PREFIX "reflect.call");
#define runtime_panic __go_panic
/*
* runtime c-called (but written in Go)
*/
void runtime_printany(Eface)
__asm__ (GOSYM_PREFIX "runtime.Printany");
void runtime_newTypeAssertionError(const String*, const String*, const String*, const String*, Eface*)
__asm__ (GOSYM_PREFIX "runtime.NewTypeAssertionError");
void runtime_newErrorString(String, Eface*)
__asm__ (GOSYM_PREFIX "runtime.NewErrorString");
void runtime_newErrorCString(const char*, Eface*)
__asm__ (GOSYM_PREFIX "runtime.NewErrorCString");
/*
* wrapped for go users
*/
void runtime_semacquire(uint32 volatile *, bool);
void runtime_semrelease(uint32 volatile *);
int32 runtime_gomaxprocsfunc(int32 n);
void runtime_procyield(uint32);
void runtime_osyield(void);
void runtime_lockOSThread(void);
void runtime_unlockOSThread(void);
bool runtime_lockedOSThread(void);
bool runtime_showframe(String, bool);
void runtime_printcreatedby(G*);
uintptr runtime_memlimit(void);
#define ISNAN(f) __builtin_isnan(f)
enum
{
UseSpanType = 0,
};
#define runtime_setitimer setitimer
void runtime_check(void);
// A list of global variables that the garbage collector must scan.
struct root_list {
struct root_list *next;
struct root {
void *decl;
size_t size;
} roots[];
};
void __go_register_gc_roots(struct root_list*);
// Size of stack space allocated using Go's allocator.
// This will be 0 when using split stacks, as in that case
// the stacks are allocated by the splitstack library.
extern uintptr runtime_stacks_sys;
struct backtrace_state;
extern struct backtrace_state *__go_get_backtrace_state(void);
extern _Bool __go_file_line(uintptr, String*, String*, intgo *);
extern byte* runtime_progname();
extern void runtime_main(void*);
extern uint32 runtime_in_callers;
int32 getproccount(void);
#define PREFETCH(p) __builtin_prefetch(p)
void __go_set_closure(void*);
void* __go_get_closure(void);
bool runtime_gcwaiting(void);
void runtime_badsignal(int);
Defer* runtime_newdefer(void);
void runtime_freedefer(Defer*);
struct time_now_ret
{
int64_t sec;
int32_t nsec;
};
struct time_now_ret now() __asm__ (GOSYM_PREFIX "time.now")
__attribute__ ((no_split_stack));