Retro68/gcc/newlib/libc/sys/linux/linuxthreads/internals.h

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/* Linuxthreads - a simple clone()-based implementation of Posix */
/* threads for Linux. */
/* Copyright (C) 1996 Xavier Leroy (Xavier.Leroy@inria.fr) */
/* */
/* This program is free software; you can redistribute it and/or */
/* modify it under the terms of the GNU Library General Public License */
/* as published by the Free Software Foundation; either version 2 */
/* of the License, or (at your option) any later version. */
/* */
/* This program is distributed in the hope that it will be useful, */
/* but WITHOUT ANY WARRANTY; without even the implied warranty of */
/* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the */
/* GNU Library General Public License for more details. */
#ifndef _INTERNALS_H
#define _INTERNALS_H 1
/* Internal data structures */
/* Includes */
#include <limits.h>
#include <resolv.h>
#include <setjmp.h>
#include <signal.h>
#include <unistd.h>
#include <stackinfo.h>
#include <sys/types.h>
#include <reent.h>
#include <bits/libc-tsd.h> /* for _LIBC_TSD_KEY_N */
extern long int testandset (int *spinlock);
extern int __compare_and_swap (long int *p, long int oldval, long int newval);
#include "libc-symbols.h"
#include "pt-machine.h"
#include "semaphore.h"
#include "thread_dbP.h"
#include <hp-timing.h>
#ifndef THREAD_GETMEM
# define THREAD_GETMEM(descr, member) descr->member
#endif
#ifndef THREAD_GETMEM_NC
# define THREAD_GETMEM_NC(descr, member) descr->member
#endif
#ifndef THREAD_SETMEM
# define THREAD_SETMEM(descr, member, value) descr->member = (value)
#endif
#ifndef THREAD_SETMEM_NC
# define THREAD_SETMEM_NC(descr, member, value) descr->member = (value)
#endif
/* Arguments passed to thread creation routine */
struct pthread_start_args {
void * (*start_routine)(void *); /* function to run */
void * arg; /* its argument */
sigset_t mask; /* initial signal mask for thread */
int schedpolicy; /* initial scheduling policy (if any) */
struct __sched_param schedparam; /* initial scheduling parameters (if any) */
};
/* We keep thread specific data in a special data structure, a two-level
array. The top-level array contains pointers to dynamically allocated
arrays of a certain number of data pointers. So we can implement a
sparse array. Each dynamic second-level array has
PTHREAD_KEY_2NDLEVEL_SIZE
entries. This value shouldn't be too large. */
#define PTHREAD_KEY_2NDLEVEL_SIZE 32
/* We need to address PTHREAD_KEYS_MAX key with PTHREAD_KEY_2NDLEVEL_SIZE
keys in each subarray. */
#define PTHREAD_KEY_1STLEVEL_SIZE \
((PTHREAD_KEYS_MAX + PTHREAD_KEY_2NDLEVEL_SIZE - 1) \
/ PTHREAD_KEY_2NDLEVEL_SIZE)
typedef void (*destr_function)(void *);
struct pthread_key_struct {
int in_use; /* already allocated? */
destr_function destr; /* destruction routine */
};
#define PTHREAD_START_ARGS_INITIALIZER(fct) \
{ (void *(*) (void *)) fct, NULL, {{0, }}, 0, { 0 } }
/* The type of thread descriptors */
typedef struct _pthread_descr_struct * pthread_descr;
/* Callback interface for removing the thread from waiting on an
object if it is cancelled while waiting or about to wait.
This hold a pointer to the object, and a pointer to a function
which ``extricates'' the thread from its enqueued state.
The function takes two arguments: pointer to the wait object,
and a pointer to the thread. It returns 1 if an extrication
actually occured, and hence the thread must also be signalled.
It returns 0 if the thread had already been extricated. */
typedef struct _pthread_extricate_struct {
void *pu_object;
int (*pu_extricate_func)(void *, pthread_descr);
} pthread_extricate_if;
/* Atomic counter made possible by compare_and_swap */
struct pthread_atomic {
long p_count;
int p_spinlock;
};
/* Context info for read write locks. The pthread_rwlock_info structure
is information about a lock that has been read-locked by the thread
in whose list this structure appears. The pthread_rwlock_context
is embedded in the thread context and contains a pointer to the
head of the list of lock info structures, as well as a count of
read locks that are untracked, because no info structure could be
allocated for them. */
struct _pthread_rwlock_t;
typedef struct _pthread_rwlock_info {
struct _pthread_rwlock_info *pr_next;
struct _pthread_rwlock_t *pr_lock;
int pr_lock_count;
} pthread_readlock_info;
struct _pthread_descr_struct {
union {
struct {
pthread_descr self; /* Pointer to this structure */
} data;
void *__padding[16];
} p_header;
pthread_descr p_nextlive, p_prevlive;
/* Double chaining of active threads */
pthread_descr p_nextwaiting; /* Next element in the queue holding the thr */
pthread_descr p_nextlock; /* can be on a queue and waiting on a lock */
pthread_t p_tid; /* Thread identifier */
int p_pid; /* PID of Unix process */
int p_priority; /* Thread priority (== 0 if not realtime) */
struct _pthread_fastlock * p_lock; /* Spinlock for synchronized accesses */
int p_signal; /* last signal received */
sigjmp_buf * p_signal_jmp; /* where to siglongjmp on a signal or NULL */
sigjmp_buf * p_cancel_jmp; /* where to siglongjmp on a cancel or NULL */
char p_terminated; /* true if terminated e.g. by pthread_exit */
char p_detached; /* true if detached */
char p_exited; /* true if the assoc. process terminated */
void * p_retval; /* placeholder for return value */
int p_retcode; /* placeholder for return code */
pthread_descr p_joining; /* thread joining on that thread or NULL */
struct _pthread_cleanup_buffer * p_cleanup; /* cleanup functions */
char p_cancelstate; /* cancellation state */
char p_canceltype; /* cancellation type (deferred/async) */
char p_canceled; /* cancellation request pending */
struct _reent * p_reentp; /* pointer to reent struct */
struct _reent p_reent; /* reentrant structure for newlib */
int * p_h_errnop; /* pointer to used h_errno variable */
int p_h_errno; /* error returned by last netdb function */
char * p_in_sighandler; /* stack address of sighandler, or NULL */
char p_sigwaiting; /* true if a sigwait() is in progress */
struct pthread_start_args p_start_args; /* arguments for thread creation */
void ** p_specific[PTHREAD_KEY_1STLEVEL_SIZE]; /* thread-specific data */
void * p_libc_specific[_LIBC_TSD_KEY_N]; /* thread-specific data for libc */
int p_userstack; /* nonzero if the user provided the stack */
void *p_guardaddr; /* address of guard area or NULL */
size_t p_guardsize; /* size of guard area */
int p_nr; /* Index of descriptor in __pthread_handles */
int p_report_events; /* Nonzero if events must be reported. */
td_eventbuf_t p_eventbuf; /* Data for event. */
struct pthread_atomic p_resume_count; /* number of times restart() was
called on thread */
char p_woken_by_cancel; /* cancellation performed wakeup */
char p_condvar_avail; /* flag if conditional variable became avail */
char p_sem_avail; /* flag if semaphore became available */
pthread_extricate_if *p_extricate; /* See above */
pthread_readlock_info *p_readlock_list; /* List of readlock info structs */
pthread_readlock_info *p_readlock_free; /* Free list of structs */
int p_untracked_readlock_count; /* Readlocks not tracked by list */
struct __res_state *p_resp; /* Pointer to resolver state */
struct __res_state p_res; /* per-thread resolver state */
int p_inheritsched; /* copied from the thread attribute */
#if HP_TIMING_AVAIL
hp_timing_t p_cpuclock_offset; /* Initial CPU clock for thread. */
#endif
/* New elements must be added at the end. */
} __attribute__ ((__aligned__(32))); /* We need to align the structure so that
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doubles are aligned properly. This is 8
bytes on MIPS and 16 bytes on MIPS64.
32 bytes might give better cache
utilization. */
/* The type of thread handles. */
typedef struct pthread_handle_struct * pthread_handle;
struct pthread_handle_struct {
struct _pthread_fastlock h_lock; /* Fast lock for sychronized access */
pthread_descr h_descr; /* Thread descriptor or NULL if invalid */
char * h_bottom; /* Lowest address in the stack thread */
};
/* The type of messages sent to the thread manager thread */
struct pthread_request {
pthread_descr req_thread; /* Thread doing the request */
enum { /* Request kind */
REQ_CREATE, REQ_FREE, REQ_PROCESS_EXIT, REQ_MAIN_THREAD_EXIT,
REQ_POST, REQ_DEBUG, REQ_KICK, REQ_FOR_EACH_THREAD
} req_kind;
union { /* Arguments for request */
struct { /* For REQ_CREATE: */
const pthread_attr_t * attr; /* thread attributes */
void * (*fn)(void *); /* start function */
void * arg; /* argument to start function */
sigset_t mask; /* signal mask */
} create;
struct { /* For REQ_FREE: */
pthread_t thread_id; /* identifier of thread to free */
} free;
struct { /* For REQ_PROCESS_EXIT: */
int code; /* exit status */
} exit;
void * post; /* For REQ_POST: the semaphore */
struct { /* For REQ_FOR_EACH_THREAD: callback */
void (*fn)(void *, pthread_descr);
void *arg;
} for_each;
} req_args;
};
/* Signals used for suspend/restart and for cancellation notification. */
extern int __pthread_sig_restart;
extern int __pthread_sig_cancel;
/* Signal used for interfacing with gdb */
extern int __pthread_sig_debug;
/* Global array of thread handles, used for validating a thread id
and retrieving the corresponding thread descriptor. Also used for
mapping the available stack segments. */
extern struct pthread_handle_struct __pthread_handles[PTHREAD_THREADS_MAX];
/* Descriptor of the initial thread */
extern struct _pthread_descr_struct __pthread_initial_thread;
/* Descriptor of the manager thread */
extern struct _pthread_descr_struct __pthread_manager_thread;
/* Descriptor of the main thread */
extern pthread_descr __pthread_main_thread;
/* Limit between the stack of the initial thread (above) and the
stacks of other threads (below). Aligned on a STACK_SIZE boundary.
Initially 0, meaning that the current thread is (by definition)
the initial thread. */
extern char *__pthread_initial_thread_bos;
/* Indicate whether at least one thread has a user-defined stack (if 1),
or all threads have stacks supplied by LinuxThreads (if 0). */
extern int __pthread_nonstandard_stacks;
/* File descriptor for sending requests to the thread manager.
Initially -1, meaning that __pthread_initialize_manager must be called. */
extern int __pthread_manager_request;
/* Other end of the pipe for sending requests to the thread manager. */
extern int __pthread_manager_reader;
/* Limits of the thread manager stack. */
extern char *__pthread_manager_thread_bos;
extern char *__pthread_manager_thread_tos;
#ifdef FLOATING_STACKS
/* Maximum stack size. */
extern size_t __pthread_max_stacksize;
#endif
/* Pending request for a process-wide exit */
extern int __pthread_exit_requested, __pthread_exit_code;
/* Set to 1 by gdb if we're debugging */
extern volatile int __pthread_threads_debug;
/* Globally enabled events. */
extern volatile td_thr_events_t __pthread_threads_events;
/* Pointer to descriptor of thread with last event. */
extern volatile pthread_descr __pthread_last_event;
/* Flag which tells whether we are executing on SMP kernel. */
extern int __pthread_smp_kernel;
/* Return the handle corresponding to a thread id */
static inline pthread_handle thread_handle(pthread_t id)
{
return &__pthread_handles[id % PTHREAD_THREADS_MAX];
}
/* Validate a thread handle. Must have acquired h->h_spinlock before. */
static inline int invalid_handle(pthread_handle h, pthread_t id)
{
return h->h_descr == NULL || h->h_descr->p_tid != id || h->h_descr->p_terminated;
}
static inline int nonexisting_handle(pthread_handle h, pthread_t id)
{
return h->h_descr == NULL || h->h_descr->p_tid != id;
}
/* Fill in defaults left unspecified by pt-machine.h. */
/* We round up a value with page size. */
#ifndef page_roundup
#define page_roundup(v,p) ((((size_t) (v)) + (p) - 1) & ~((p) - 1))
#endif
/* The page size we can get from the system. This should likely not be
changed by the machine file but, you never know. */
#ifndef PAGE_SIZE
#define PAGE_SIZE (sysconf (_SC_PAGE_SIZE))
#endif
/* The max size of the thread stack segments. If the default
THREAD_SELF implementation is used, this must be a power of two and
a multiple of PAGE_SIZE. */
#ifndef STACK_SIZE
#define STACK_SIZE (2 * 1024 * 1024)
#endif
/* The initial size of the thread stack. Must be a multiple of PAGE_SIZE. */
#ifndef INITIAL_STACK_SIZE
#define INITIAL_STACK_SIZE (4 * PAGE_SIZE)
#endif
/* Size of the thread manager stack. The "- 32" avoids wasting space
with some malloc() implementations. */
#ifndef THREAD_MANAGER_STACK_SIZE
#define THREAD_MANAGER_STACK_SIZE (2 * PAGE_SIZE - 32)
#endif
/* The base of the "array" of thread stacks. The array will grow down from
here. Defaults to the calculated bottom of the initial application
stack. */
#ifndef THREAD_STACK_START_ADDRESS
#define THREAD_STACK_START_ADDRESS __pthread_initial_thread_bos
#endif
/* Get some notion of the current stack. Need not be exactly the top
of the stack, just something somewhere in the current frame. */
#ifndef CURRENT_STACK_FRAME
#define CURRENT_STACK_FRAME ({ char __csf; &__csf; })
#endif
/* Recover thread descriptor for the current thread */
extern pthread_descr __pthread_find_self (void) __attribute__ ((__const__));
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static inline pthread_descr thread_self (void) __attribute__ ((__const__));
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static inline pthread_descr thread_self (void)
{
#ifdef THREAD_SELF
return THREAD_SELF;
#else
char *sp = CURRENT_STACK_FRAME;
if (sp >= __pthread_initial_thread_bos)
return &__pthread_initial_thread;
else if (sp >= __pthread_manager_thread_bos
&& sp < __pthread_manager_thread_tos)
return &__pthread_manager_thread;
else if (__pthread_nonstandard_stacks)
return __pthread_find_self();
else
#ifdef _STACK_GROWS_DOWN
return (pthread_descr)(((unsigned long)sp | (STACK_SIZE-1))+1) - 1;
#else
return (pthread_descr)((unsigned long)sp &~ (STACK_SIZE-1));
#endif
#endif
}
/* If MEMORY_BARRIER isn't defined in pt-machine.h, assume the architecture
doesn't need a memory barrier instruction (e.g. Intel x86). Still we
need the compiler to respect the barrier and emit all outstanding
operations which modify memory. Some architectures distinguish between
full, read and write barriers. */
#ifndef MEMORY_BARRIER
#define MEMORY_BARRIER() asm ("" : : : "memory")
#endif
#ifndef READ_MEMORY_BARRIER
#define READ_MEMORY_BARRIER() MEMORY_BARRIER()
#endif
#ifndef WRITE_MEMORY_BARRIER
#define WRITE_MEMORY_BARRIER() MEMORY_BARRIER()
#endif
/* Max number of times we must spin on a spinlock calling sched_yield().
After MAX_SPIN_COUNT iterations, we put the calling thread to sleep. */
#ifndef MAX_SPIN_COUNT
#define MAX_SPIN_COUNT 50
#endif
/* Max number of times the spinlock in the adaptive mutex implementation
spins actively on SMP systems. */
#ifndef MAX_ADAPTIVE_SPIN_COUNT
#define MAX_ADAPTIVE_SPIN_COUNT 100
#endif
/* Duration of sleep (in nanoseconds) when we can't acquire a spinlock
after MAX_SPIN_COUNT iterations of sched_yield().
With the 2.0 and 2.1 kernels, this MUST BE > 2ms.
(Otherwise the kernel does busy-waiting for realtime threads,
giving other threads no chance to run.) */
#ifndef SPIN_SLEEP_DURATION
#define SPIN_SLEEP_DURATION 2000001
#endif
/* Debugging */
#ifdef DEBUG
#include <assert.h>
#define ASSERT assert
#define MSG __pthread_message
#else
#define ASSERT(x)
#define MSG(msg,arg...)
#endif
/* Internal global functions */
extern void __pthread_do_exit (void *retval, char *currentframe)
__attribute__ ((__noreturn__));
extern void __pthread_destroy_specifics (void);
extern void __pthread_perform_cleanup (char *currentframe);
extern void __pthread_init_max_stacksize (void);
extern int __pthread_initialize_manager (void);
extern void __pthread_message (char * fmt, ...);
extern int __pthread_manager (void *reqfd);
extern int __pthread_manager_event (void *reqfd);
extern void __pthread_manager_sighandler (int sig);
extern void __pthread_reset_main_thread (void);
extern void __pthread_once_fork_prepare (void);
extern void __pthread_once_fork_parent (void);
extern void __pthread_once_fork_child (void);
extern void __flockfilelist (void);
extern void __funlockfilelist (void);
extern void __fresetlockfiles (void);
extern void __pthread_manager_adjust_prio (int thread_prio);
extern void __pthread_initialize_minimal (void);
extern int __pthread_attr_setguardsize (pthread_attr_t *__attr,
size_t __guardsize);
extern int __pthread_attr_getguardsize (const pthread_attr_t *__attr,
size_t *__guardsize);
extern int __pthread_attr_setstackaddr (pthread_attr_t *__attr,
void *__stackaddr);
extern int __pthread_attr_getstackaddr (const pthread_attr_t *__attr,
void **__stackaddr);
extern int __pthread_attr_setstacksize (pthread_attr_t *__attr,
size_t __stacksize);
extern int __pthread_attr_getstacksize (const pthread_attr_t *__attr,
size_t *__stacksize);
extern int __pthread_attr_setstack (pthread_attr_t *__attr, void *__stackaddr,
size_t __stacksize);
extern int __pthread_attr_getstack (const pthread_attr_t *__attr, void **__stackaddr,
size_t *__stacksize);
extern int __pthread_getconcurrency (void);
extern int __pthread_setconcurrency (int __level);
extern int __pthread_mutex_timedlock (pthread_mutex_t *__mutex,
const struct timespec *__abstime);
extern int __pthread_mutexattr_getpshared (const pthread_mutexattr_t *__attr,
int *__pshared);
extern int __pthread_mutexattr_setpshared (pthread_mutexattr_t *__attr,
int __pshared);
extern int __pthread_mutexattr_gettype (const pthread_mutexattr_t *__attr,
int *__kind);
extern void __pthread_kill_other_threads_np (void);
extern void __pthread_restart_old(pthread_descr th);
extern void __pthread_suspend_old(pthread_descr self);
extern int __pthread_timedsuspend_old(pthread_descr self, const struct timespec *abs);
extern void __pthread_restart_new(pthread_descr th);
extern void __pthread_suspend_new(pthread_descr self);
extern int __pthread_timedsuspend_new(pthread_descr self, const struct timespec *abs);
extern void __pthread_wait_for_restart_signal(pthread_descr self);
extern int __pthread_yield (void);
extern int __pthread_rwlock_timedrdlock (pthread_rwlock_t *__restrict __rwlock,
__const struct timespec *__restrict
__abstime);
extern int __pthread_rwlock_timedwrlock (pthread_rwlock_t *__restrict __rwlock,
__const struct timespec *__restrict
__abstime);
extern int __pthread_rwlockattr_destroy (pthread_rwlockattr_t *__attr);
extern int __pthread_barrierattr_getpshared (__const pthread_barrierattr_t *
__restrict __attr,
int *__restrict __pshared);
extern int __pthread_spin_lock (pthread_spinlock_t *__lock);
extern int __pthread_spin_trylock (pthread_spinlock_t *__lock);
extern int __pthread_spin_unlock (pthread_spinlock_t *__lock);
extern int __pthread_spin_init (pthread_spinlock_t *__lock, int __pshared);
extern int __pthread_spin_destroy (pthread_spinlock_t *__lock);
extern int __pthread_clock_gettime (hp_timing_t freq, struct timespec *tp);
extern void __pthread_clock_settime (hp_timing_t offset);
/* Global pointers to old or new suspend functions */
extern void (*__pthread_restart)(pthread_descr);
extern void (*__pthread_suspend)(pthread_descr);
extern int (*__pthread_timedsuspend)(pthread_descr, const struct timespec *);
/* Prototypes for the function without cancelation support when the
normal version has it. */
extern int __libc_close (int fd);
extern int __libc_nanosleep (const struct timespec *requested_time,
struct timespec *remaining);
/* Prototypes for some of the new semaphore functions. */
extern int __new_sem_post (sem_t * sem);
extern int __new_sem_init (sem_t *__sem, int __pshared, unsigned int __value);
extern int __new_sem_wait (sem_t *__sem);
extern int __new_sem_trywait (sem_t *__sem);
extern int __new_sem_getvalue (sem_t *__restrict __sem, int *__restrict __sval);
extern int __new_sem_destroy (sem_t *__sem);
/* Prototypes for compatibility functions. */
extern int __pthread_attr_init_2_1 (pthread_attr_t *__attr);
extern int __pthread_attr_init_2_0 (pthread_attr_t *__attr);
extern int __pthread_create_2_1 (pthread_t *__restrict __thread1,
const pthread_attr_t *__attr,
void *(*__start_routine) (void *),
void *__restrict __arg);
extern int __pthread_create_2_0 (pthread_t *__restrict __thread1,
const pthread_attr_t *__attr,
void *(*__start_routine) (void *),
void *__restrict arg);
/* The functions called the signal events. */
extern void __linuxthreads_create_event (void);
extern void __linuxthreads_death_event (void);
extern void __linuxthreads_reap_event (void);
/* This function is called to initialize the pthread library. */
extern void __pthread_initialize (void);
#endif /* internals.h */