/* * File : ringbuffer.c * This file is part of RT-Thread RTOS * COPYRIGHT (C) 2012, RT-Thread Development Team * * 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. * * 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 General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * * Change Logs: * Date Author Notes * 2012-09-30 Bernard first version. * 2013-05-08 Grissiom reimplement * 2016-08-18 heyuanjie add interface */ #include #include #include rt_inline enum rt_ringbuffer_state rt_ringbuffer_status(struct rt_ringbuffer *rb) { if (rb->read_index == rb->write_index) { if (rb->read_mirror == rb->write_mirror) return RT_RINGBUFFER_EMPTY; else return RT_RINGBUFFER_FULL; } return RT_RINGBUFFER_HALFFULL; } void rt_ringbuffer_init(struct rt_ringbuffer *rb, rt_uint8_t *pool, rt_int16_t size) { RT_ASSERT(rb != RT_NULL); RT_ASSERT(size > 0); /* initialize read and write index */ rb->read_mirror = rb->read_index = 0; rb->write_mirror = rb->write_index = 0; /* set buffer pool and size */ rb->buffer_ptr = pool; rb->buffer_size = RT_ALIGN_DOWN(size, RT_ALIGN_SIZE); } RTM_EXPORT(rt_ringbuffer_init); /** * put a block of data into ring buffer */ rt_size_t rt_ringbuffer_put(struct rt_ringbuffer *rb, const rt_uint8_t *ptr, rt_uint16_t length) { rt_uint16_t size; RT_ASSERT(rb != RT_NULL); /* whether has enough space */ size = rt_ringbuffer_space_len(rb); /* no space */ if (size == 0) return 0; /* drop some data */ if (size < length) length = size; if (rb->buffer_size - rb->write_index > length) { /* read_index - write_index = empty space */ memcpy(&rb->buffer_ptr[rb->write_index], ptr, length); /* this should not cause overflow because there is enough space for * length of data in current mirror */ rb->write_index += length; return length; } memcpy(&rb->buffer_ptr[rb->write_index], &ptr[0], rb->buffer_size - rb->write_index); memcpy(&rb->buffer_ptr[0], &ptr[rb->buffer_size - rb->write_index], length - (rb->buffer_size - rb->write_index)); /* we are going into the other side of the mirror */ rb->write_mirror = ~rb->write_mirror; rb->write_index = length - (rb->buffer_size - rb->write_index); return length; } RTM_EXPORT(rt_ringbuffer_put); /** * put a block of data into ring buffer * * When the buffer is full, it will discard the old data. */ rt_size_t rt_ringbuffer_put_force(struct rt_ringbuffer *rb, const rt_uint8_t *ptr, rt_uint16_t length) { rt_uint16_t space_length; RT_ASSERT(rb != RT_NULL); space_length = rt_ringbuffer_space_len(rb); if (length > rb->buffer_size) { ptr = &ptr[length - rb->buffer_size]; length = rb->buffer_size; } if (rb->buffer_size - rb->write_index > length) { /* read_index - write_index = empty space */ memcpy(&rb->buffer_ptr[rb->write_index], ptr, length); /* this should not cause overflow because there is enough space for * length of data in current mirror */ rb->write_index += length; if (length > space_length) rb->read_index = rb->write_index; return length; } memcpy(&rb->buffer_ptr[rb->write_index], &ptr[0], rb->buffer_size - rb->write_index); memcpy(&rb->buffer_ptr[0], &ptr[rb->buffer_size - rb->write_index], length - (rb->buffer_size - rb->write_index)); /* we are going into the other side of the mirror */ rb->write_mirror = ~rb->write_mirror; rb->write_index = length - (rb->buffer_size - rb->write_index); if (length > space_length) { rb->read_mirror = ~rb->read_mirror; rb->read_index = rb->write_index; } return length; } RTM_EXPORT(rt_ringbuffer_put_force); /** * get data from ring buffer */ rt_size_t rt_ringbuffer_get(struct rt_ringbuffer *rb, rt_uint8_t *ptr, rt_uint16_t length) { rt_size_t size; RT_ASSERT(rb != RT_NULL); /* whether has enough data */ size = rt_ringbuffer_data_len(rb); /* no data */ if (size == 0) return 0; /* less data */ if (size < length) length = size; if (rb->buffer_size - rb->read_index > length) { /* copy all of data */ memcpy(ptr, &rb->buffer_ptr[rb->read_index], length); /* this should not cause overflow because there is enough space for * length of data in current mirror */ rb->read_index += length; return length; } memcpy(&ptr[0], &rb->buffer_ptr[rb->read_index], rb->buffer_size - rb->read_index); memcpy(&ptr[rb->buffer_size - rb->read_index], &rb->buffer_ptr[0], length - (rb->buffer_size - rb->read_index)); /* we are going into the other side of the mirror */ rb->read_mirror = ~rb->read_mirror; rb->read_index = length - (rb->buffer_size - rb->read_index); return length; } RTM_EXPORT(rt_ringbuffer_get); /** * put a character into ring buffer */ rt_size_t rt_ringbuffer_putchar(struct rt_ringbuffer *rb, const rt_uint8_t ch) { RT_ASSERT(rb != RT_NULL); /* whether has enough space */ if (!rt_ringbuffer_space_len(rb)) return 0; rb->buffer_ptr[rb->write_index] = ch; /* flip mirror */ if (rb->write_index == rb->buffer_size-1) { rb->write_mirror = ~rb->write_mirror; rb->write_index = 0; } else { rb->write_index++; } return 1; } RTM_EXPORT(rt_ringbuffer_putchar); /** * put a character into ring buffer * * When the buffer is full, it will discard one old data. */ rt_size_t rt_ringbuffer_putchar_force(struct rt_ringbuffer *rb, const rt_uint8_t ch) { enum rt_ringbuffer_state old_state; RT_ASSERT(rb != RT_NULL); old_state = rt_ringbuffer_status(rb); rb->buffer_ptr[rb->write_index] = ch; /* flip mirror */ if (rb->write_index == rb->buffer_size-1) { rb->write_mirror = ~rb->write_mirror; rb->write_index = 0; if (old_state == RT_RINGBUFFER_FULL) { rb->read_mirror = ~rb->read_mirror; rb->read_index = rb->write_index; } } else { rb->write_index++; if (old_state == RT_RINGBUFFER_FULL) rb->read_index = rb->write_index; } return 1; } RTM_EXPORT(rt_ringbuffer_putchar_force); /** * get a character from a ringbuffer */ rt_size_t rt_ringbuffer_getchar(struct rt_ringbuffer *rb, rt_uint8_t *ch) { RT_ASSERT(rb != RT_NULL); /* ringbuffer is empty */ if (!rt_ringbuffer_data_len(rb)) return 0; /* put character */ *ch = rb->buffer_ptr[rb->read_index]; if (rb->read_index == rb->buffer_size-1) { rb->read_mirror = ~rb->read_mirror; rb->read_index = 0; } else { rb->read_index++; } return 1; } RTM_EXPORT(rt_ringbuffer_getchar); /** * get the size of data in rb */ rt_size_t rt_ringbuffer_data_len(struct rt_ringbuffer *rb) { switch (rt_ringbuffer_status(rb)) { case RT_RINGBUFFER_EMPTY: return 0; case RT_RINGBUFFER_FULL: return rb->buffer_size; case RT_RINGBUFFER_HALFFULL: default: if (rb->write_index > rb->read_index) return rb->write_index - rb->read_index; else return rb->buffer_size - (rb->read_index - rb->write_index); }; } RTM_EXPORT(rt_ringbuffer_data_len); /** * empty the rb */ void rt_ringbuffer_reset(struct rt_ringbuffer *rb) { RT_ASSERT(rb != RT_NULL); rb->read_mirror = 0; rb->read_index = 0; rb->write_mirror = 0; rb->write_index = 0; } RTM_EXPORT(rt_ringbuffer_reset); #ifdef RT_USING_HEAP struct rt_ringbuffer* rt_ringbuffer_create(rt_uint16_t size) { struct rt_ringbuffer *rb; rt_uint8_t *pool; RT_ASSERT(size > 0); size = RT_ALIGN_DOWN(size, RT_ALIGN_SIZE); rb = rt_malloc(sizeof(struct rt_ringbuffer)); if (rb == RT_NULL) goto exit; pool = rt_malloc(size); if (pool == RT_NULL) { rt_free(rb); goto exit; } rt_ringbuffer_init(rb, pool, size); exit: return rb; } RTM_EXPORT(rt_ringbuffer_create); void rt_ringbuffer_destroy(struct rt_ringbuffer *rb) { RT_ASSERT(rb != RT_NULL); rt_free(rb->buffer_ptr); rt_free(rb); } RTM_EXPORT(rt_ringbuffer_destroy); #endif