/* Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. * The ASF licenses this file to You under the Apache License, Version 2.0 * (the "License"); you may not use this file except in compliance with * the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "fspr_arch_threadproc.h" static struct beos_key key_table[BEOS_MAX_DATAKEYS]; static struct beos_private_data *beos_data[BEOS_MAX_DATAKEYS]; static sem_id lock; APR_DECLARE(fspr_status_t) fspr_threadkey_private_create(fspr_threadkey_t **key, void (*dest)(void *), fspr_pool_t *pool) { (*key) = (fspr_threadkey_t *)fspr_palloc(pool, sizeof(fspr_threadkey_t)); if ((*key) == NULL) { return APR_ENOMEM; } (*key)->pool = pool; acquire_sem(lock); for ((*key)->key=0; (*key)->key < BEOS_MAX_DATAKEYS; (*key)->key++){ if (key_table[(*key)->key].assigned == 0){ key_table[(*key)->key].assigned = 1; key_table[(*key)->key].destructor = dest; release_sem(lock); return APR_SUCCESS; } } release_sem(lock); return APR_ENOMEM; } APR_DECLARE(fspr_status_t) fspr_threadkey_private_get(void **new, fspr_threadkey_t *key) { thread_id tid; int i, index=0; tid = find_thread(NULL); for (i=0;idata){ /* it's been used */ if (beos_data[i]->td == tid){ index = i; } } } if (index == 0){ /* no storage for thread so we can't get anything... */ return APR_ENOMEM; } if ((key->key < BEOS_MAX_DATAKEYS) && (key_table)){ acquire_sem(key_table[key->key].lock); if (key_table[key->key].count){ (*new) = (void*)beos_data[index]->data[key->key]; } else { (*new) = NULL; } release_sem(key_table[key->key].lock); } else { (*new) = NULL; } return APR_SUCCESS; } APR_DECLARE(fspr_status_t) fspr_threadkey_private_set(void *priv, fspr_threadkey_t *key) { thread_id tid; int i,index = 0, ret = 0; tid = find_thread(NULL); for (i=0; i < BEOS_MAX_DATAKEYS; i++){ if (beos_data[i]->data){ if (beos_data[i]->td == tid){index = i;} } } if (index==0){ /* not yet been allocated */ for (i=0; i< BEOS_MAX_DATAKEYS; i++){ if (! beos_data[i]->data){ /* we'll take this one... */ index = i; beos_data[i]->data = (const void **)malloc(sizeof(void *) * BEOS_MAX_DATAKEYS); memset((void *)beos_data[i]->data, 0, sizeof(void *) * BEOS_MAX_DATAKEYS); beos_data[i]->count = (int)malloc(sizeof(int)); beos_data[i]->td = (thread_id)malloc(sizeof(thread_id)); beos_data[i]->td = tid; } } } if (index == 0){ /* we're out of luck.. */ return APR_ENOMEM; } if ((key->key < BEOS_MAX_DATAKEYS) && (key_table)){ acquire_sem(key_table[key->key].lock); if (key_table[key->key].count){ if (beos_data[index]->data[key->key] == NULL){ if (priv != NULL){ beos_data[index]->count++; key_table[key->key].count++; } } else { if (priv == NULL){ beos_data[index]->count--; key_table[key->key].count--; } } beos_data[index]->data[key->key] = priv; ret = 1; } else { ret = 0; } release_sem(key_table[key->key].lock); } if (ret) return APR_SUCCESS; return APR_ENOMEM; } APR_DECLARE(fspr_status_t) fspr_threadkey_private_delete(fspr_threadkey_t *key) { if (key->key < BEOS_MAX_DATAKEYS){ acquire_sem(key_table[key->key].lock); if (key_table[key->key].count == 1){ key_table[key->key].destructor = NULL; key_table[key->key].count = 0; } release_sem(key_table[key->key].lock); } else { return APR_ENOMEM; } return APR_SUCCESS; } APR_DECLARE(fspr_status_t) fspr_threadkey_data_get(void **data, const char *key, fspr_threadkey_t *threadkey) { return fspr_pool_userdata_get(data, key, threadkey->pool); } APR_DECLARE(fspr_status_t) fspr_threadkey_data_set(void *data, const char *key, fspr_status_t (*cleanup) (void *), fspr_threadkey_t *threadkey) { return fspr_pool_userdata_set(data, key, cleanup, threadkey->pool); } APR_DECLARE(fspr_status_t) fspr_os_threadkey_get(fspr_os_threadkey_t *thekey, fspr_threadkey_t *key) { *thekey = key->key; return APR_SUCCESS; } APR_DECLARE(fspr_status_t) fspr_os_threadkey_put(fspr_threadkey_t **key, fspr_os_threadkey_t *thekey, fspr_pool_t *pool) { if (pool == NULL) { return APR_ENOPOOL; } if ((*key) == NULL) { (*key) = (fspr_threadkey_t *)fspr_pcalloc(pool, sizeof(fspr_threadkey_t)); (*key)->pool = pool; } (*key)->key = *thekey; return APR_SUCCESS; }