/* * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ // A ring buffer to hold arbitrary data. Provides no thread safety. Unless // otherwise specified, functions return 0 on success and -1 on error. #include "ring_buffer.h" #include // size_t #include #include enum Wrap { SAME_WRAP, DIFF_WRAP }; typedef struct { size_t read_pos; size_t write_pos; size_t element_count; size_t element_size; enum Wrap rw_wrap; char* data; } buf_t; // Get address of region(s) from which we can read data. // If the region is contiguous, |data_ptr_bytes_2| will be zero. // If non-contiguous, |data_ptr_bytes_2| will be the size in bytes of the second // region. Returns room available to be read or |element_count|, whichever is // smaller. static size_t GetBufferReadRegions(buf_t* buf, size_t element_count, void** data_ptr_1, size_t* data_ptr_bytes_1, void** data_ptr_2, size_t* data_ptr_bytes_2) { const size_t readable_elements = WebRtc_available_read(buf); const size_t read_elements = (readable_elements < element_count ? readable_elements : element_count); const size_t margin = buf->element_count - buf->read_pos; // Check to see if read is not contiguous. if (read_elements > margin) { // Write data in two blocks that wrap the buffer. *data_ptr_1 = buf->data + buf->read_pos * buf->element_size; *data_ptr_bytes_1 = margin * buf->element_size; *data_ptr_2 = buf->data; *data_ptr_bytes_2 = (read_elements - margin) * buf->element_size; } else { *data_ptr_1 = buf->data + buf->read_pos * buf->element_size; *data_ptr_bytes_1 = read_elements * buf->element_size; *data_ptr_2 = NULL; *data_ptr_bytes_2 = 0; } return read_elements; } int WebRtc_CreateBuffer(void** handle, size_t element_count, size_t element_size) { buf_t* self = NULL; if (handle == NULL) { return -1; } self = malloc(sizeof(buf_t)); if (self == NULL) { return -1; } *handle = self; self->data = malloc(element_count * element_size); if (self->data == NULL) { free(self); self = NULL; return -1; } self->element_count = element_count; self->element_size = element_size; return 0; } int WebRtc_InitBuffer(void* handle) { buf_t* self = (buf_t*) handle; if (self == NULL) { return -1; } self->read_pos = 0; self->write_pos = 0; self->rw_wrap = SAME_WRAP; // Initialize buffer to zeros memset(self->data, 0, self->element_count * self->element_size); return 0; } int WebRtc_FreeBuffer(void* handle) { buf_t* self = (buf_t*) handle; if (self == NULL) { return -1; } free(self->data); free(self); return 0; } size_t WebRtc_ReadBuffer(void* handle, void** data_ptr, void* data, size_t element_count) { buf_t* self = (buf_t*) handle; if (self == NULL) { return 0; } if (data == NULL) { return 0; } if (data_ptr == NULL) { return 0; } { void* buf_ptr_1 = NULL; void* buf_ptr_2 = NULL; size_t buf_ptr_bytes_1 = 0; size_t buf_ptr_bytes_2 = 0; const size_t read_count = GetBufferReadRegions(self, element_count, &buf_ptr_1, &buf_ptr_bytes_1, &buf_ptr_2, &buf_ptr_bytes_2); if (buf_ptr_bytes_2 > 0) { // We have a wrap around when reading the buffer. Copy the buffer data to // |data| and point to it. memcpy(data, buf_ptr_1, buf_ptr_bytes_1); memcpy(((char*) data) + buf_ptr_bytes_1, buf_ptr_2, buf_ptr_bytes_2); *data_ptr = data; } else { *data_ptr = buf_ptr_1; } // Update read position WebRtc_MoveReadPtr(handle, (int) read_count); return read_count; } } size_t WebRtc_WriteBuffer(void* handle, const void* data, size_t element_count) { buf_t* self = (buf_t*) handle; if (self == NULL) { return 0; } if (data == NULL) { return 0; } { const size_t free_elements = WebRtc_available_write(handle); const size_t write_elements = (free_elements < element_count ? free_elements : element_count); size_t n = write_elements; const size_t margin = self->element_count - self->write_pos; if (write_elements > margin) { // Buffer wrap around when writing. memcpy(self->data + self->write_pos * self->element_size, data, margin * self->element_size); self->write_pos = 0; n -= margin; self->rw_wrap = DIFF_WRAP; } memcpy(self->data + self->write_pos * self->element_size, ((const char*) data) + ((write_elements - n) * self->element_size), n * self->element_size); self->write_pos += n; return write_elements; } } int WebRtc_MoveReadPtr(void* handle, int element_count) { buf_t* self = (buf_t*) handle; if (self == NULL) { return 0; } { // We need to be able to take care of negative changes, hence use "int" // instead of "size_t". const int free_elements = (int) WebRtc_available_write(handle); const int readable_elements = (int) WebRtc_available_read(handle); int read_pos = (int) self->read_pos; if (element_count > readable_elements) { element_count = readable_elements; } if (element_count < -free_elements) { element_count = -free_elements; } read_pos += element_count; if (read_pos > (int) self->element_count) { // Buffer wrap around. Restart read position and wrap indicator. read_pos -= (int) self->element_count; self->rw_wrap = SAME_WRAP; } if (read_pos < 0) { // Buffer wrap around. Restart read position and wrap indicator. read_pos += (int) self->element_count; self->rw_wrap = DIFF_WRAP; } self->read_pos = (size_t) read_pos; return element_count; } } size_t WebRtc_available_read(const void* handle) { const buf_t* self = (buf_t*) handle; if (self == NULL) { return 0; } if (self->rw_wrap == SAME_WRAP) { return self->write_pos - self->read_pos; } else { return self->element_count - self->read_pos + self->write_pos; } } size_t WebRtc_available_write(const void* handle) { const buf_t* self = (buf_t*) handle; if (self == NULL) { return 0; } return self->element_count - WebRtc_available_read(handle); }