/* * This file contains MCC library API functions implementation * * Copyright (C) 2014-2015 Freescale Semiconductor, Inc. All Rights Reserved. * * * SPDX-License-Identifier: GPL-2.0+ and/or BSD-3-Clause * The GPL-2.0+ license for this file can be found in the COPYING.GPL file * included with this distribution or at * http://www.gnu.org/licenses/gpl-2.0.html * The BSD-3-Clause License for this file can be found in the COPYING.BSD file * included with this distribution or at * http://opensource.org/licenses/BSD-3-Clause */ #include "mcc_config.h" #if (MCC_OS_USED == MCC_MQX) #include #include "mcc_config.h" #include "mcc_common.h" #include "mcc_api.h" #include "mcc_mqx.h" #elif (MCC_OS_USED == MCC_LINUX) #include #include #include #include #endif const char * const init_string = MCC_INIT_STRING; const char * const version_string = MCC_VERSION_STRING; static int mcc_recv_common_part(MCC_ENDPOINT *endpoint, unsigned int timeout_ms, MCC_RECEIVE_LIST **list); static int mcc_get_buffer_internal(void **buffer, MCC_MEM_SIZE *buf_size, unsigned int timeout_ms); static int mcc_free_buffer_internal(void *buffer); /*! * \brief This function initializes the Multi Core Communication subsystem for a given node. * * This function should only be called once per node (once in MQX, once per a process in Linux). * It tries to initialize the bookkeeping structure when the init_string member of this structure * is not equal to MCC_INIT_STRING, i.e. when no other core had performed the initialization yet. * Note, that this way of bookkeeping data re-initialization protection is not powerful enough and * the user application should not rely on this method. Instead, the application should be designed * to unambiguously assign the core that will perform the MCC initialization. * Clear the shared memory before the first core is attempting to initialize the MCC * (in some cases MCC_INIT_STRING remains in the shared memory after the application reset and could * cause that the bookkeeping data structure is not initialized correctly). * * \param[in] node Node number that will be used in endpoints created by this process. * * \return MCC_SUCCESS * \return MCC_ERR_SEMAPHORE (semaphore handling error) * \return MCC_ERR_INT (interrupt registration error) * \return MCC_ERR_VERSION (incorrect MCC version used - compatibility issue) * \return MCC_ERR_OSSYNC (OS synchronization module(s) initialization failed) * * \see mcc_destroy * \see MCC_BOOKEEPING_STRUCT */ int mcc_initialize(MCC_NODE node) { int i,j = 0; int return_value = MCC_SUCCESS; MCC_SIGNAL tmp_signals_received = {(MCC_SIGNAL_TYPE)0, {(MCC_CORE)0, (MCC_NODE)0, (MCC_PORT)0}}; /* Initialize synchronization module for shared data protection */ return_value = mcc_init_semaphore(MCC_SHMEM_SEMAPHORE_NUMBER); if(return_value != MCC_SUCCESS) return return_value; /* Initialize all necessary OS synchronization module(s) (for unblocking tasks waiting for new received data and for unblocking tasks waiting for a free buffer) */ return_value = mcc_init_os_sync(); if(return_value != MCC_SUCCESS) return return_value; /* Register CPU-to-CPU interrupt for inter-core signaling */ //mcc_register_cpu_to_cpu_isr(MCC_CORE0_CPU_TO_CPU_VECTOR); return_value = mcc_register_cpu_to_cpu_isr(); if(return_value != MCC_SUCCESS) return return_value; /* Initialize the bookeeping structure */ bookeeping_data = (MCC_BOOKEEPING_STRUCT *)mcc_get_bookeeping_data(); MCC_DCACHE_INVALIDATE_MLINES(bookeeping_data, sizeof(MCC_BOOKEEPING_STRUCT)); if(strcmp(bookeeping_data->init_string, init_string) != 0) { /* MCC not initialized yet, do it now */ /* Zero it all - no guarantee Linux or uboot didnt touch it before it was reserved */ memset((void*) bookeeping_data, 0, sizeof(struct mcc_bookeeping_struct)); /* Set init_string in case it has not been set yet by another core */ mcc_memcpy((void*)init_string, bookeeping_data->init_string, (unsigned int)sizeof(bookeeping_data->init_string)); /* Set version_string */ mcc_memcpy((void*)version_string, bookeeping_data->version_string, (unsigned int)sizeof(bookeeping_data->version_string)); /* Initialize the free list */ bookeeping_data->free_list.head = (MCC_RECEIVE_BUFFER*)MCC_MEM_VIRT_TO_PHYS(&bookeeping_data->r_buffers[0]); bookeeping_data->free_list.tail = (MCC_RECEIVE_BUFFER*)MCC_MEM_VIRT_TO_PHYS(&bookeeping_data->r_buffers[MCC_ATTR_NUM_RECEIVE_BUFFERS-1]); /* Initialize receive buffers */ for(i=0; ir_buffers[i].next = (MCC_RECEIVE_BUFFER*)MCC_MEM_VIRT_TO_PHYS(&bookeeping_data->r_buffers[i+1]); } bookeeping_data->r_buffers[MCC_ATTR_NUM_RECEIVE_BUFFERS-1].next = null; /* Initialize signal queues */ for(i=0; isignals_received[i][j] = tmp_signals_received; } bookeeping_data->signal_queue_head[i] = 0; bookeeping_data->signal_queue_tail[i] = 0; } /* Mark all endpoint ports as free */ for(i=0; iendpoint_table[i].endpoint.port = MCC_RESERVED_PORT_NUMBER; } } else { /* MCC already initialized - check the major number of the version string to ensure compatibility */ if(strncmp(bookeeping_data->version_string, version_string, 4) != 0) { return_value = MCC_ERR_VERSION; } } MCC_DCACHE_FLUSH_MLINES(bookeeping_data, sizeof(MCC_BOOKEEPING_STRUCT)); return return_value; } /*! * \brief This function de-initializes the Multi Core Communication subsystem for a given node. * * The function frees all resources of the node. Deletes all endpoints and frees any buffers that may have been queued there. * * \param[in] node Node number to be deinitialized. * * \return MCC_SUCCESS * \return MCC_ERR_SEMAPHORE (semaphore handling error) * \return MCC_ERR_OSSYNC (OS synchronization module(s) deinitialization failed) * * \see mcc_initialize */ int mcc_destroy(MCC_NODE node) { int i = 0, return_value; /* Semaphore-protected section start */ return_value = mcc_get_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* All endpoints of the particular node have to be removed from the endpoint table */ MCC_DCACHE_INVALIDATE_MLINES(&bookeeping_data->endpoint_table[0], MCC_ATTR_MAX_RECEIVE_ENDPOINTS * sizeof(MCC_ENDPOINT_MAP_ITEM)); for(i = 0; i < MCC_ATTR_MAX_RECEIVE_ENDPOINTS; i++) { if (bookeeping_data->endpoint_table[i].endpoint.node == node) { /* Remove the endpoint from the table */ mcc_remove_endpoint(bookeeping_data->endpoint_table[i].endpoint); } } /* Semaphore-protected section end */ return_value = mcc_release_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* Deinitialize synchronization module */ mcc_deinit_semaphore(MCC_SHMEM_SEMAPHORE_NUMBER); /* De-initialize OS synchronization module(s) (for unblocking tasks waiting for new data and for unblocking tasks waiting for a free buffer */ return_value = mcc_deinit_os_sync(); if(return_value != MCC_SUCCESS) return return_value; return return_value; } /*! * \brief This function creates an endpoint. * * The function creates an endpoint on the local node with the specified port number. * The core and node provided in the endpoint must match the caller's core and * node, and the port argument must match the endpoint port. * * \param[out] endpoint Pointer to the endpoint triplet to be created. * \param[in] port Port number. * * \return MCC_SUCCESS * \return MCC_ERR_NOMEM (maximum number of endpoints exceeded) * \return MCC_ERR_ENDPOINT (invalid value for port or endpoint already registered) * \return MCC_ERR_SEMAPHORE (semaphore handling error) * * \see mcc_destroy_endpoint * \see MCC_ENDPOINT */ int mcc_create_endpoint(MCC_ENDPOINT *endpoint, MCC_PORT port) { int return_value = MCC_SUCCESS; /* Fill the endpoint structure */ endpoint->core = (MCC_CORE)MCC_CORE_NUMBER; endpoint->node = (MCC_NODE)MCC_NODE_NUMBER; endpoint->port = (MCC_PORT)port; /* Semaphore-protected section start */ return_value = mcc_get_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* Add new endpoint data into the book-keeping structure */ return_value = mcc_register_endpoint(*endpoint); if(return_value != MCC_SUCCESS) { mcc_release_semaphore(); return return_value; } /* Semaphore-protected section end */ return_value = mcc_release_semaphore(); if(return_value != MCC_SUCCESS) return return_value; return return_value; } /*! * \brief This function destroys an endpoint. * * The function destroys an endpoint on the local node and frees any buffers that may be queued. * * \param[in] endpoint Pointer to the endpoint triplet to be deleted. * * \return MCC_SUCCESS * \return MCC_ERR_ENDPOINT (the endpoint doesn't exist) * \return MCC_ERR_SEMAPHORE (semaphore handling error) * * \see mcc_create_endpoint * \see MCC_ENDPOINT */ int mcc_destroy_endpoint(MCC_ENDPOINT *endpoint) { int return_value = MCC_SUCCESS; /* Semaphore-protected section start */ return_value = mcc_get_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* Remove the endpoint data from the book-keeping structure */ return_value = mcc_remove_endpoint(*endpoint); if(return_value != MCC_SUCCESS) { mcc_release_semaphore(); return return_value; } /* Clear OS synchronization module parts associated with the endpoint to be destroyed */ mcc_clear_os_sync_for_ep(endpoint); /* Semaphore-protected section end */ return_value = mcc_release_semaphore(); if(return_value != MCC_SUCCESS) return return_value; return return_value; } /*! * \brief This function sends a message to an endpoint. * * The message is copied into the MCC buffer and the destination core is signaled. * * \param[in] src_endpoint Pointer to the local endpoint identifying the source endpoint. * \param[in] dest_endpoint Pointer to the destination endpoint to send the message to. * \param[in] msg Pointer to the message to be sent. * \param[in] msg_size Size of the message to be sent in bytes. * \param[in] timeout_ms Timeout, in milliseconds, to wait for a free buffer. A value of 0 means don't wait (non-blocking call). A value of 0xffffffff means wait forever (blocking call). * * \return MCC_SUCCESS * \return MCC_ERR_ENDPOINT (the endpoint does not exist) * \return MCC_ERR_SEMAPHORE (semaphore handling error) * \return MCC_ERR_INVAL (the msg_size exceeds the size of a data buffer) * \return MCC_ERR_TIMEOUT (timeout exceeded before a buffer became available) * \return MCC_ERR_NOMEM (no free buffer available and timeout_ms set to 0) * \return MCC_ERR_SQ_FULL (signal queue is full) * * \see mcc_recv * \see mcc_recv_nocopy * \see MCC_ENDPOINT */ int mcc_send(MCC_ENDPOINT *src_endpoint, MCC_ENDPOINT *dest_endpoint, void *msg, MCC_MEM_SIZE msg_size, unsigned int timeout_ms) { int return_value; MCC_RECEIVE_LIST *list; MCC_RECEIVE_BUFFER * buf; MCC_SIGNAL affiliated_signal; MCC_MEM_SIZE buffer_size; /* Reuse the mcc_get_buffer_internal() function to get the MCC buffer pointer. */ return_value = mcc_get_buffer_internal((void**)&buf, &buffer_size, timeout_ms); if(return_value != MCC_SUCCESS) return return_value; /* Check if the size of the message to be sent does not exceed the size of the mcc buffer */ if(msg_size > buffer_size) { while(MCC_SUCCESS != mcc_free_buffer_internal(buf)) {}; return MCC_ERR_INVAL; } /* Semaphore-protected section start */ return_value = mcc_get_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* As the mcc_get_buffer_internal() returns the pointer to the data field, it is necessary to adjust the pointer to point at the MCC buffer structure beginning. */ buf = (MCC_RECEIVE_BUFFER *)((unsigned int)buf - (unsigned int)(&(((MCC_RECEIVE_BUFFER*)0)->data))); /* Copy the message into the MCC receive buffer */ MCC_DCACHE_INVALIDATE_MLINES((void*)buf, sizeof(MCC_RECEIVE_BUFFER)); mcc_memcpy(msg, (void*)buf->data, (unsigned int)msg_size); mcc_memcpy((void*)src_endpoint, (void*)&buf->source, sizeof(MCC_ENDPOINT)); buf->data_len = msg_size; MCC_DCACHE_FLUSH_MLINES((void*)buf, sizeof(MCC_RECEIVE_BUFFER)); /* Get list of buffers kept by the particular endpoint */ list = mcc_get_endpoint_list(*dest_endpoint); if(list == null) { /* The endpoint does not exists (has not been registered so far), free the buffer and return immediately - error */ /* Enqueue the buffer back into the free list */ MCC_DCACHE_INVALIDATE_MLINES((void*)&bookeeping_data->free_list, sizeof(MCC_RECEIVE_LIST*)); mcc_queue_buffer(&bookeeping_data->free_list, buf); mcc_release_semaphore(); return MCC_ERR_ENDPOINT; } /* Write the signal type into the signal queue of the particular core */ affiliated_signal.type = BUFFER_QUEUED; affiliated_signal.destination = *dest_endpoint; return_value = mcc_queue_signal(dest_endpoint->core, affiliated_signal); if(return_value != MCC_SUCCESS) { /* Signal queue is full, free the buffer and return immediately - error */ MCC_DCACHE_INVALIDATE_MLINES((void*)&bookeeping_data->free_list, sizeof(MCC_RECEIVE_LIST*)); mcc_queue_buffer(&bookeeping_data->free_list, buf); mcc_release_semaphore(); return return_value; } /* Enqueue the buffer into the endpoint buffer list */ mcc_queue_buffer(list, buf); /* Semaphore-protected section end */ return_value = mcc_release_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* Signal the other core by generating the CPU-to-CPU interrupt */ return_value = mcc_generate_cpu_to_cpu_interrupt(); return return_value; } /*! * \private * * \brief This function dequeues a buffer from the free list. * * This is an internal implementation of the mcc_get_buffer() function. It is called * either from the mcc_send() or from mcc_get_buffer() when the non-copy-send * mechanism is enabled by the MCC_SEND_RECV_NOCOPY_API_ENABLED macro in mcc_config.h. * * \param[out] buffer Pointer to the MCC buffer dequeued from the free list. * \param[out] buf_size Pointer to an MCC_MEM_SIZE that is used for passing the size of the dequeued MCC buffer to the application. * \param[in] timeout_ms Timeout, in milliseconds, to wait for a free buffer. A value of 0 means don't wait (non-blocking call). A value of 0xffffffff means wait forever (blocking call). * * \return MCC_SUCCESS * \return MCC_ERR_SEMAPHORE (semaphore handling error) * \return MCC_ERR_TIMEOUT (timeout exceeded before a buffer became available) * \return MCC_ERR_NOMEM (no free buffer available and timeout_ms set to 0) * * \see mcc_send_nocopy * \see mcc_send * \see mcc_get_buffer */ static int mcc_get_buffer_internal(void **buffer, MCC_MEM_SIZE *buf_size, unsigned int timeout_ms) { int return_value; MCC_RECEIVE_BUFFER * buf = null; *buffer = null; /* Semaphore-protected section start */ return_value = mcc_get_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* Dequeue the buffer from the free list */ MCC_DCACHE_INVALIDATE_MLINES((void*)&bookeeping_data->free_list, sizeof(MCC_RECEIVE_LIST*)); buf = mcc_dequeue_buffer(&bookeeping_data->free_list); /* Semaphore-protected section end */ mcc_release_semaphore(); if(buf == null) { /* Non-blocking call */ if(timeout_ms == 0) { return MCC_ERR_NOMEM; } else { /* Wait for the buffer freed event */ return_value = mcc_wait_for_buffer_freed((MCC_RECEIVE_BUFFER **)&buf, timeout_ms); if(MCC_SUCCESS != return_value) { return return_value; } } } /* Return the MCC buffer size and the pointer to the dequeued MCC buffer */ *buf_size = (MCC_MEM_SIZE)sizeof(bookeeping_data->r_buffers[0].data); *buffer = (void*)buf->data; return MCC_SUCCESS; } #if MCC_SEND_RECV_NOCOPY_API_ENABLED /*! * \brief This function dequeues a buffer from the free list. * * The application has take the responsibility for MCC buffer de-allocation and * filling the data to be sent into the pre-allocated MCC buffer. * * \param[out] buffer Pointer to the MCC buffer dequeued from the free list. * \param[out] buf_size Pointer to an MCC_MEM_SIZE that is used for passing the size of the dequeued MCC buffer to the application. * \param[in] timeout_ms Timeout, in milliseconds, to wait for a free buffer. A value of 0 means don't wait (non-blocking call). A value of 0xffffffff means wait forever (blocking call). * * \return MCC_SUCCESS * \return MCC_ERR_SEMAPHORE (semaphore handling error) * \return MCC_ERR_TIMEOUT (timeout exceeded before a buffer became available) * \return MCC_ERR_NOMEM (no free buffer available and timeout_ms set to 0) * * \see mcc_send_nocopy */ int mcc_get_buffer(void **buffer, MCC_MEM_SIZE *buf_size, unsigned int timeout_ms) { return mcc_get_buffer_internal(buffer, buf_size, timeout_ms); } /*! * \brief This function sends a message to an endpoint. The data is NOT copied * from the user-app. buffer but the pointer to already filled message buffer is * provided. * * The application has to take the responsibility for: * 1. MCC buffer de-allocation * 2. filling the data to be sent into the pre-allocated MCC buffer * 3. not exceeding the buffer size when filling the data (MCC_ATTR_BUFFER_SIZE_IN_BYTES) * * Once the data cache is used on the target platform it is good to have MCC buffers * in shared RAM aligned to the cache line size in order not to corrupt entities placed * just before and just after the MCC buffer when flushing the MCC buffer content into * the shared RAM. It is also the application responsibility to flush the data in * that case. If the alignment condition is not fulfilled the application * has to take care about the data cache coherency. * The following scenarios can happen: * A. Data cache is OFF: * - No cache operation needs to be done, the application just * 1. calls the mcc_get_buffer() function, * 2. fills data into the provided MCC buffer, * 3. and finally issues the mcc_send_nocopy() function. * B. Data cache is ON, shared RAM MCC buffers ALIGNED to the cache line size: * - The application has to perform following steps: * 1. call the mcc_get_buffer() to get the pointer to a free message buffer * 2. copy data to be sent into the message buffer * 3. flush all cache lines occupied by the message buffer new data * (maximum of MCC_ATTR_BUFFER_SIZE_IN_BYTES bytes). * 4. call the mcc_send_nocopy() with the correct buffer pointer and the message size passed * C. Data cache is ON, shared RAM MCC buffers NOT ALIGNED: * - The application has to perform following steps: * 1. call the mcc_get_buffer() to get the pointer to a free message buffer * 2. grab the hw semaphore by calling the mcc_get_semaphore() low level MCC function. * 3. invalidate all cache lines occupied by data to be filled into the free message buffer. * (maximum of MCC_ATTR_BUFFER_SIZE_IN_BYTES bytes). * 4. copy data to be sent into the message buffer. * 5. flush all cache lines occupied by the message buffer new data * (maximum of MCC_ATTR_BUFFER_SIZE_IN_BYTES bytes). * 6. release the hw semaphore by calling the mcc_release_semaphore() low level MCC function. * 7. call the mcc_send_nocopy() with the correct buffer pointer and the message size passed. * * After the mcc_send_nocopy() function is issued the message buffer is no more owned * by the sending task and must not be touched anymore unless the mcc_send_nocopy() * function fails and returns an error. In that case the application should try * to re-issue the mcc_send_nocopy() again and if it is still not possible to send * the message and the application wants to give it up from whatever reasons * (for instance the MCC_ERR_ENDPOINT error is returned meaning the endpoint * has not been created yet) the mcc_free_buffer() function could be called, * passing the pointer to the buffer to be freed as a parameter. * * \param[in] src_endpoint Pointer to the local endpoint identifying the source endpoint. * \param[in] dest_endpoint Pointer to the destination endpoint to send the message to. * \param[in] buffer_p Pointer to the MCC buffer of the shared memory where the * data to be sent is stored. * \param[in] msg_size Size of the message to be sent in bytes. * * \return MCC_SUCCESS * \return MCC_ERR_INVAL (the msg_size exceeds the size of a data buffer) * \return MCC_ERR_ENDPOINT (the endpoint does not exist) * \return MCC_ERR_SEMAPHORE (semaphore handling error) * \return MCC_ERR_SQ_FULL (signal queue is full) * * \see mcc_send * \see mcc_get_buffer * \see MCC_ENDPOINT */ int mcc_send_nocopy(MCC_ENDPOINT *src_endpoint, MCC_ENDPOINT *dest_endpoint, void *buffer_p, MCC_MEM_SIZE msg_size) { int return_value; MCC_RECEIVE_BUFFER * buf; MCC_RECEIVE_LIST *list; MCC_SIGNAL affiliated_signal; /* Check if the size of the message to be sent does not exceed the size of the mcc buffer */ if(msg_size > sizeof(bookeeping_data->r_buffers[0].data)) { return MCC_ERR_INVAL; } /* Semaphore-protected section start */ return_value = mcc_get_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* Get list of buffers kept by the particular endpoint */ list = mcc_get_endpoint_list(*dest_endpoint); if(list == null) { /* The endpoint does not exists (has not been registered so far) */ mcc_release_semaphore(); return MCC_ERR_ENDPOINT; } /* Store the message size and the source endpoint in the MCC_RECEIVE_BUFFER structure */ buf = (MCC_RECEIVE_BUFFER *)((unsigned int)buffer_p - (unsigned int)(&(((MCC_RECEIVE_BUFFER*)0)->data))); MCC_DCACHE_INVALIDATE_MLINES((void*)&buf->source, sizeof(MCC_ENDPOINT) + sizeof(MCC_MEM_SIZE)); ((MCC_RECEIVE_BUFFER*)buf)->data_len = msg_size; mcc_memcpy((void*)src_endpoint, (void*)&buf->source, sizeof(MCC_ENDPOINT)); MCC_DCACHE_FLUSH_MLINES((void*)(void*)&buf->source, sizeof(MCC_ENDPOINT) + sizeof(MCC_MEM_SIZE)); /* Write the signal type into the signal queue of the particular core */ affiliated_signal.type = BUFFER_QUEUED; affiliated_signal.destination = *dest_endpoint; return_value = mcc_queue_signal(dest_endpoint->core, affiliated_signal); if(return_value != MCC_SUCCESS) { /* Signal queue is full - error */ mcc_release_semaphore(); return return_value; } /* Enqueue the buffer into the endpoint buffer list */ mcc_queue_buffer(list, (MCC_RECEIVE_BUFFER*)buf); /* Semaphore-protected section end */ mcc_release_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* Signal the other core by generating the CPU-to-CPU interrupt */ return_value = mcc_generate_cpu_to_cpu_interrupt(); return return_value; } #endif /* MCC_SEND_RECV_NOCOPY_API_ENABLED */ /*! * \brief This function receives a message from the specified endpoint if one is available. * The data is copied from the receive buffer into the user supplied buffer. * * This is the "receive with copy" version of the MCC receive function. This version is simple * to use but it requires copying data from shared memory into the user space buffer. * The user has no obligation or burden to manage the shared memory buffers. * * \param[out] src_endpoint Pointer to the MCC_ENDPOINT structure to be filled by the endpoint identifying the message sender. * \param[in] dest_endpoint Pointer to the local receiving endpoint to receive from. * \param[in] buffer Pointer to the user-app. buffer where data will be copied into. * \param[in] buffer_size The maximum number of bytes to copy. * \param[out] recv_size Pointer to an MCC_MEM_SIZE that will contain the number of bytes actually copied into the buffer. * \param[in] timeout_ms Timeout, in milliseconds, to wait for a free buffer. A value of 0 means don't wait (non-blocking call). A value of 0xffffffff means wait forever (blocking call). * * \return MCC_SUCCESS * \return MCC_ERR_ENDPOINT (the endpoint does not exist) * \return MCC_ERR_SEMAPHORE (semaphore handling error) * \return MCC_ERR_TIMEOUT (timeout exceeded before a new message came) * * \see mcc_send * \see mcc_recv_nocopy * \see MCC_ENDPOINT */ int mcc_recv(MCC_ENDPOINT *src_endpoint, MCC_ENDPOINT *dest_endpoint, void *buffer, MCC_MEM_SIZE buffer_size, MCC_MEM_SIZE *recv_size, unsigned int timeout_ms) { MCC_RECEIVE_LIST *list = null; MCC_RECEIVE_BUFFER * buf; MCC_SIGNAL affiliated_signal; MCC_ENDPOINT tmp_destination = {(MCC_CORE)0, (MCC_NODE)0, (MCC_PORT)0}; int return_value, i = 0; return_value = mcc_recv_common_part(dest_endpoint, timeout_ms, (MCC_RECEIVE_LIST**)&list); if(return_value != MCC_SUCCESS) return return_value; /* Semaphore-protected section start */ return_value = mcc_get_semaphore(); if(return_value != MCC_SUCCESS) return return_value; MCC_DCACHE_INVALIDATE_MLINES((void*)list, sizeof(MCC_RECEIVE_LIST*)); if(list->head == (MCC_RECEIVE_BUFFER*)0) { /* Buffer not dequeued before the timeout */ mcc_release_semaphore(); return MCC_ERR_TIMEOUT; } /* Copy the message from the MCC receive buffer into the user-app. buffer */ MCC_DCACHE_INVALIDATE_MLINES((void*)&list->head->source, sizeof(MCC_ENDPOINT) + sizeof(MCC_MEM_SIZE)); mcc_memcpy((void*)&list->head->source, (void*)src_endpoint, sizeof(MCC_ENDPOINT)); if (list->head->data_len > buffer_size) { list->head->data_len = buffer_size; } *recv_size = (MCC_MEM_SIZE)(list->head->data_len); MCC_DCACHE_INVALIDATE_MLINES((void*)&list->head->data, list->head->data_len); mcc_memcpy((void*)list->head->data, buffer, list->head->data_len); /* Dequeue the buffer from the endpoint list */ list->head = (MCC_RECEIVE_BUFFER*)MCC_MEM_VIRT_TO_PHYS(list->head); buf = mcc_dequeue_buffer(list); /* Enqueue the buffer into the free list */ MCC_DCACHE_INVALIDATE_MLINES((void*)&bookeeping_data->free_list, sizeof(MCC_RECEIVE_LIST*)); mcc_queue_buffer(&bookeeping_data->free_list, buf); /* Notify all cores (except of itself) via CPU-to-CPU interrupt that a buffer has been freed */ affiliated_signal.type = BUFFER_FREED; affiliated_signal.destination = tmp_destination; for (i=0; ihead == (MCC_RECEIVE_BUFFER*)0) { /* Buffer not dequeued before the timeout */ mcc_release_semaphore(); return MCC_ERR_TIMEOUT; } /* Get the message pointer from the head of the receive buffer list */ MCC_DCACHE_INVALIDATE_MLINES((void*)&list->head->data, list->head->data_len); *buffer_p = (void*)&list->head->data; MCC_DCACHE_INVALIDATE_MLINES((void*)&list->head->source, sizeof(MCC_ENDPOINT) + sizeof(MCC_MEM_SIZE)); mcc_memcpy((void*)&list->head->source, (void*)src_endpoint, sizeof(MCC_ENDPOINT)); *recv_size = (MCC_MEM_SIZE)(list->head->data_len); /* Dequeue the buffer from the endpoint list */ mcc_dequeue_buffer(list); /* Semaphore-protected section end */ return_value = mcc_release_semaphore(); if(return_value != MCC_SUCCESS) return return_value; return return_value; } #endif /* MCC_SEND_RECV_NOCOPY_API_ENABLED */ /*! * \private * * \brief This function is common part for mcc_recv() and mcc_recv_nocopy() function. * * It tries to get the list of buffers kept by the particular endpoint. If the list is empty * it waits for a new message until the timeout expires. * * \param[in] endpoint Pointer to the receiving endpoint to receive from. * \param[in] timeout_ms Timeout, in milliseconds, to wait for a free buffer. A value of 0 means don't wait (non-blocking call). A value of 0xffffffff means wait forever (blocking call). * \param[out] list Pointer to the list of buffers kept by the particular endpoint. * * \return MCC_SUCCESS * \return MCC_ERR_ENDPOINT (the endpoint does not exist) * \return MCC_ERR_SEMAPHORE (semaphore handling error) * \return MCC_ERR_TIMEOUT (timeout exceeded before a new message came) * * \see mcc_recv * \see mcc_recv_nocopy * \see MCC_ENDPOINT */ static int mcc_recv_common_part(MCC_ENDPOINT *endpoint, unsigned int timeout_ms, MCC_RECEIVE_LIST **list) { MCC_RECEIVE_LIST *tmp_list; int return_value; /* Semaphore-protected section start */ return_value = mcc_get_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* Get list of buffers kept by the particular endpoint */ tmp_list = mcc_get_endpoint_list(*endpoint); /* Semaphore-protected section end */ return_value = mcc_release_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* The endpoint is not valid */ if(tmp_list == null) { return MCC_ERR_ENDPOINT; } if(tmp_list->head == (MCC_RECEIVE_BUFFER*)0) { /* Non-blocking call */ if(timeout_ms == 0) { return MCC_ERR_TIMEOUT; } /* Blocking call */ else { /* Wait for the buffer queued event */ return_value = mcc_wait_for_buffer_queued(endpoint, timeout_ms); if(MCC_SUCCESS != return_value) { return return_value; } } } else { tmp_list->head = (MCC_RECEIVE_BUFFER*)MCC_MEM_PHYS_TO_VIRT(tmp_list->head); } /* Clear event bit specified for the particular endpoint */ mcc_clear_os_sync_for_ep(endpoint); *list = (MCC_RECEIVE_LIST*)tmp_list; return MCC_SUCCESS; } /*! * \brief This function returns the number of buffers currently queued at the endpoint. * * The function checks if messages are available on a receive endpoint. While the call only checks the * availability of messages, it does not dequeue them. * * \param[in] endpoint Pointer to the endpoint structure. * \param[out] num_msgs Pointer to an unsigned int that will contain the number of buffers queued. * * \return MCC_SUCCESS * \return MCC_ERR_ENDPOINT (the endpoint does not exist) * \return MCC_ERR_SEMAPHORE (semaphore handling error) * * \see mcc_recv * \see mcc_recv_nocopy * \see MCC_ENDPOINT */ int mcc_msgs_available(MCC_ENDPOINT *endpoint, unsigned int *num_msgs) { unsigned int count = 0; MCC_RECEIVE_LIST *list; MCC_RECEIVE_BUFFER * buf; int return_value; /* Semaphore-protected section start */ return_value = mcc_get_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* Get list of buffers kept by the particular endpoint */ list = mcc_get_endpoint_list(*endpoint); if(list == null) { /* The endpoint does not exists (has not been registered so far), return immediately - error */ mcc_release_semaphore(); return MCC_ERR_ENDPOINT; } buf = list->head; while(buf != (MCC_RECEIVE_BUFFER*)0) { count++; MCC_DCACHE_INVALIDATE_MLINES((void*)&buf->next, sizeof(MCC_RECEIVE_BUFFER*)); buf = (MCC_RECEIVE_BUFFER*)buf->next; } *num_msgs = count; /* Semaphore-protected section end */ return_value = mcc_release_semaphore(); if(return_value != MCC_SUCCESS) return return_value; return return_value; } /*! * \private * * \brief This function frees a buffer previously returned by mcc_recv_nocopy(). * * Once the zero-copy mechanism of receiving data is used, this function * has to be called to free a buffer and to make it available for the next data * transfer. * * \param[in] buffer Pointer to the buffer to be freed. * * \return MCC_SUCCESS * \return MCC_ERR_SEMAPHORE (semaphore handling error) * * \see mcc_recv_nocopy */ static int mcc_free_buffer_internal(void *buffer) { MCC_SIGNAL affiliated_signal; MCC_ENDPOINT tmp_destination = {(MCC_CORE)0, (MCC_NODE)0, (MCC_PORT)0}; int return_value, i = 0; /* Semaphore-protected section start */ return_value = mcc_get_semaphore(); if(return_value != MCC_SUCCESS) return return_value; /* Enqueue the buffer into the free list */ MCC_DCACHE_INVALIDATE_MLINES((void*)&bookeeping_data->free_list, sizeof(MCC_RECEIVE_LIST*)); mcc_queue_buffer(&bookeeping_data->free_list, (MCC_RECEIVE_BUFFER *)((unsigned int)buffer - (unsigned int)(&(((MCC_RECEIVE_BUFFER*)0)->data)))); /* Notify all cores (except of itself) via CPU-to-CPU interrupt that a buffer has been freed */ affiliated_signal.type = BUFFER_FREED; affiliated_signal.destination = tmp_destination; for (i=0; iversion_string, (void*)info_data->version_string, (unsigned int)sizeof(bookeeping_data->version_string)); /* Semaphore-protected section end */ return_value = mcc_release_semaphore(); if(return_value != MCC_SUCCESS) return return_value; return return_value; }