Mercurial > trustbridge > nss-cmake-static
view nspr/pr/src/threads/prtpd.c @ 4:b513267f632f tip
Build DBM module
author | Andre Heinecke <andre.heinecke@intevation.de> |
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date | Tue, 05 Aug 2014 18:58:03 +0200 |
parents | 1e5118fa0cb1 |
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/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /* ** Thread Private Data ** ** There is an aribitrary limit on the number of keys that will be allocated ** by the runtime. It's largish, so it is intended to be a sanity check, not ** an impediment. ** ** There is a counter, initialized to zero and incremented every time a ** client asks for a new key, that holds the high water mark for keys. All ** threads logically have the same high water mark and are permitted to ** ask for TPD up to that key value. ** ** The vector to hold the TPD are allocated when PR_SetThreadPrivate() is ** called. The size of the vector will be some value greater than or equal ** to the current high water mark. Each thread has its own TPD length and ** vector. ** ** Threads that get private data for keys they have not set (or perhaps ** don't even exist for that thread) get a NULL return. If the key is ** beyond the high water mark, an error will be returned. */ /* ** As of this time, BeOS has its own TPD implementation. Integrating ** this standard one is a TODO for anyone with a bit of spare time on ** their hand. For now, we just #ifdef out this whole file and use ** the routines in pr/src/btthreads/ */ #ifndef XP_BEOS #include "primpl.h" #include <string.h> #if defined(WIN95) /* ** Some local variables report warnings on Win95 because the code paths ** using them are conditioned on HAVE_CUSTOME_USER_THREADS. ** The pragma suppresses the warning. ** */ #pragma warning(disable : 4101) #endif #define _PR_TPD_LIMIT 128 /* arbitary limit on the TPD slots */ static PRInt32 _pr_tpd_length = 0; /* current length of destructor vector */ static PRInt32 _pr_tpd_highwater = 0; /* next TPD key to be assigned */ static PRThreadPrivateDTOR *_pr_tpd_destructors = NULL; /* the destructors are associated with the keys, therefore asserting that the TPD key depicts the data's 'type' */ /* ** Initialize the thread private data manipulation */ void _PR_InitTPD(void) { _pr_tpd_destructors = (PRThreadPrivateDTOR*) PR_CALLOC(_PR_TPD_LIMIT * sizeof(PRThreadPrivateDTOR*)); PR_ASSERT(NULL != _pr_tpd_destructors); _pr_tpd_length = _PR_TPD_LIMIT; } /* ** Clean up the thread private data manipulation */ void _PR_CleanupTPD(void) { } /* _PR_CleanupTPD */ /* ** This routine returns a new index for per-thread-private data table. ** The index is visible to all threads within a process. This index can ** be used with the PR_SetThreadPrivate() and PR_GetThreadPrivate() routines ** to save and retrieve data associated with the index for a thread. ** ** The index independently maintains specific values for each binding thread. ** A thread can only get access to its own thread-specific-data. ** ** Upon a new index return the value associated with the index for all threads ** is NULL, and upon thread creation the value associated with all indices for ** that thread is NULL. ** ** "dtor" is the destructor function to invoke when the private ** data is set or destroyed ** ** Returns PR_FAILURE if the total number of indices will exceed the maximun ** allowed. */ PR_IMPLEMENT(PRStatus) PR_NewThreadPrivateIndex( PRUintn *newIndex, PRThreadPrivateDTOR dtor) { PRStatus rv; PRInt32 index; if (!_pr_initialized) _PR_ImplicitInitialization(); PR_ASSERT(NULL != newIndex); PR_ASSERT(NULL != _pr_tpd_destructors); index = PR_ATOMIC_INCREMENT(&_pr_tpd_highwater) - 1; /* allocate index */ if (_PR_TPD_LIMIT <= index) { PR_SetError(PR_TPD_RANGE_ERROR, 0); rv = PR_FAILURE; /* that's just wrong */ } else { _pr_tpd_destructors[index] = dtor; /* record destructor @index */ *newIndex = (PRUintn)index; /* copy into client's location */ rv = PR_SUCCESS; /* that's okay */ } return rv; } /* ** Define some per-thread-private data. ** "index" is an index into the per-thread private data table ** "priv" is the per-thread-private data ** ** If the per-thread private data table has a previously registered ** destructor function and a non-NULL per-thread-private data value, ** the destructor function is invoked. ** ** This can return PR_FAILURE if index is invalid (ie., beyond the current ** high water mark) or memory is insufficient to allocate an exanded vector. */ PR_IMPLEMENT(PRStatus) PR_SetThreadPrivate(PRUintn index, void *priv) { PRThread *self = PR_GetCurrentThread(); /* ** The index being set might not have a sufficient vector in this ** thread. But if the index has been allocated, it's okay to go ** ahead and extend this one now. */ if ((index >= _PR_TPD_LIMIT) || (index >= _pr_tpd_highwater)) { PR_SetError(PR_TPD_RANGE_ERROR, 0); return PR_FAILURE; } PR_ASSERT(((NULL == self->privateData) && (0 == self->tpdLength)) || ((NULL != self->privateData) && (0 != self->tpdLength))); if ((NULL == self->privateData) || (self->tpdLength <= index)) { void *extension = PR_CALLOC(_pr_tpd_length * sizeof(void*)); if (NULL == extension) { PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); return PR_FAILURE; } if (self->privateData) { (void)memcpy( extension, self->privateData, self->tpdLength * sizeof(void*)); PR_DELETE(self->privateData); } self->tpdLength = _pr_tpd_length; self->privateData = (void**)extension; } /* ** There wasn't much chance of having to call the destructor ** unless the slot already existed. */ else if (self->privateData[index] && _pr_tpd_destructors[index]) { void *data = self->privateData[index]; self->privateData[index] = NULL; (*_pr_tpd_destructors[index])(data); } PR_ASSERT(index < self->tpdLength); self->privateData[index] = priv; return PR_SUCCESS; } /* ** Recover the per-thread-private data for the current thread. "index" is ** the index into the per-thread private data table. ** ** The returned value may be NULL which is indistinguishable from an error ** condition. ** */ PR_IMPLEMENT(void*) PR_GetThreadPrivate(PRUintn index) { PRThread *self = PR_GetCurrentThread(); void *tpd = ((NULL == self->privateData) || (index >= self->tpdLength)) ? NULL : self->privateData[index]; return tpd; } /* ** Destroy the thread's private data, if any exists. This is called at ** thread termination time only. There should be no threading issues ** since this is being called by the thread itself. */ void _PR_DestroyThreadPrivate(PRThread* self) { #define _PR_TPD_DESTRUCTOR_ITERATIONS 4 if (NULL != self->privateData) /* we have some */ { PRBool clean; PRUint32 index; PRInt32 passes = _PR_TPD_DESTRUCTOR_ITERATIONS; PR_ASSERT(0 != self->tpdLength); do { clean = PR_TRUE; for (index = 0; index < self->tpdLength; ++index) { void *priv = self->privateData[index]; /* extract */ if (NULL != priv) /* we have data at this index */ { if (NULL != _pr_tpd_destructors[index]) { self->privateData[index] = NULL; /* precondition */ (*_pr_tpd_destructors[index])(priv); /* destroy */ clean = PR_FALSE; /* unknown side effects */ } } } } while ((--passes > 0) && !clean); /* limit # of passes */ /* ** We give up after a fixed number of passes. Any non-NULL ** thread-private data value with a registered destructor ** function is not destroyed. */ memset(self->privateData, 0, self->tpdLength * sizeof(void*)); } } /* _PR_DestroyThreadPrivate */ #endif /* !XP_BEOS */