/* * Generic FIFO32 component, based on FIFO8. * * Copyright (c) 2016 Jean-Christophe Dubois * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version * 2 of the License, or (at your option) any later version. * * You should have received a copy of the GNU General Public License along * with this program; if not, see . */ #ifndef FIFO32_H #define FIFO32_H #include "qemu/fifo8.h" typedef struct { Fifo8 fifo; } Fifo32; /** * fifo32_create: * @fifo: struct Fifo32 to initialise with new FIFO * @capacity: capacity of the newly created FIFO expressed in 32 bit words * * Create a FIFO of the specified size. Clients should call fifo32_destroy() * when finished using the fifo. The FIFO is initially empty. */ static inline void fifo32_create(Fifo32 *fifo, uint32_t capacity) { fifo8_create(&fifo->fifo, capacity * sizeof(uint32_t)); } /** * fifo32_destroy: * @fifo: FIFO to cleanup * * Cleanup a FIFO created with fifo32_create(). Frees memory created for FIFO * storage. The FIFO is no longer usable after this has been called. */ static inline void fifo32_destroy(Fifo32 *fifo) { fifo8_destroy(&fifo->fifo); } /** * fifo32_num_free: * @fifo: FIFO to check * * Return the number of free uint32_t slots in the FIFO. * * Returns: Number of free 32 bit words. */ static inline uint32_t fifo32_num_free(Fifo32 *fifo) { return DIV_ROUND_UP(fifo8_num_free(&fifo->fifo), sizeof(uint32_t)); } /** * fifo32_num_used: * @fifo: FIFO to check * * Return the number of used uint32_t slots in the FIFO. * * Returns: Number of used 32 bit words. */ static inline uint32_t fifo32_num_used(Fifo32 *fifo) { return DIV_ROUND_UP(fifo8_num_used(&fifo->fifo), sizeof(uint32_t)); } /** * fifo32_push: * @fifo: FIFO to push to * @data: 32 bits data word to push * * Push a 32 bits data word to the FIFO. Behaviour is undefined if the FIFO * is full. Clients are responsible for checking for fullness using * fifo32_is_full(). */ static inline void fifo32_push(Fifo32 *fifo, uint32_t data) { int i; for (i = 0; i < sizeof(data); i++) { fifo8_push(&fifo->fifo, data & 0xff); data >>= 8; } } /** * fifo32_push_all: * @fifo: FIFO to push to * @data: data to push * @size: number of 32 bit words to push * * Push a 32 bit word array to the FIFO. Behaviour is undefined if the FIFO * is full. Clients are responsible for checking the space left in the FIFO * using fifo32_num_free(). */ static inline void fifo32_push_all(Fifo32 *fifo, const uint32_t *data, uint32_t num) { int i; for (i = 0; i < num; i++) { fifo32_push(fifo, data[i]); } } /** * fifo32_pop: * @fifo: fifo to pop from * * Pop a 32 bits data word from the FIFO. Behaviour is undefined if the FIFO * is empty. Clients are responsible for checking for emptiness using * fifo32_is_empty(). * * Returns: The popped 32 bits data word. */ static inline uint32_t fifo32_pop(Fifo32 *fifo) { uint32_t ret = 0; int i; for (i = 0; i < sizeof(uint32_t); i++) { ret |= (fifo8_pop(&fifo->fifo) << (i * 8)); } return ret; } /** * There is no fifo32_pop_buf() because the data is not stored in the buffer * as a set of native-order words. */ /** * fifo32_reset: * @fifo: FIFO to reset * * Reset a FIFO. All data is discarded and the FIFO is emptied. */ static inline void fifo32_reset(Fifo32 *fifo) { fifo8_reset(&fifo->fifo); } /** * fifo32_is_empty: * @fifo: FIFO to check * * Check if a FIFO is empty. * * Returns: True if the fifo is empty, false otherwise. */ static inline bool fifo32_is_empty(Fifo32 *fifo) { return fifo8_is_empty(&fifo->fifo); } /** * fifo32_is_full: * @fifo: FIFO to check * * Check if a FIFO is full. * * Returns: True if the fifo is full, false otherwise. */ static inline bool fifo32_is_full(Fifo32 *fifo) { return fifo8_num_free(&fifo->fifo) < sizeof(uint32_t); } #define VMSTATE_FIFO32(_field, _state) VMSTATE_FIFO8(_field.fifo, _state) #endif /* FIFO32_H */