/*####COPYRIGHTBEGIN#### ------------------------------------------- Copyright (C) 2004 by Steve Karg 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. 59 Temple Place - Suite 330 Boston, MA 02111-1307 USA. As a special exception, if other files instantiate templates or use macros or inline functions from this file, or you compile this file and link it with other works to produce a work based on this file, this file does not by itself cause the resulting work to be covered by the GNU General Public License. However the source code for this file must still be made available in accordance with section (3) of the GNU General Public License. This exception does not invalidate any other reasons why a work based on this file might be covered by the GNU General Public License. ------------------------------------------- ####COPYRIGHTEND####*/ /* Functional Description: Generic ring buffer library for deeply embedded system. See the unit tests for usage examples. */ #include #include #include "ringbuf.h" /**************************************************************************** * DESCRIPTION: Returns the empty/full status of the ring buffer * RETURN: true if the ring buffer is empty, false if it is not. * ALGORITHM: none * NOTES: none *****************************************************************************/ bool Ringbuf_Empty(RING_BUFFER const *b) { return (b->count == 0); } /**************************************************************************** * DESCRIPTION: Looks at the data from the head of the list without removing it * RETURN: none * ALGORITHM: none * NOTES: none *****************************************************************************/ char *Ringbuf_Get_Front(RING_BUFFER const *b) { return (b->count ? &(b->data[b->head * b->element_size]) : NULL); } /**************************************************************************** * DESCRIPTION: Gets the data from the front of the list, and removes it * RETURN: none * ALGORITHM: none * NOTES: none *****************************************************************************/ char *Ringbuf_Pop_Front(RING_BUFFER *b) { char *data = NULL; // return value if (b->count) { data = &(b->data[b->head * b->element_size]); b->head++; if (b->head >= b->element_count) b->head = 0; b->count--; } return data; } /**************************************************************************** * DESCRIPTION: Adds an element of data to the ring buffer * RETURN: true on succesful add, false if not added * ALGORITHM: none * NOTES: none *****************************************************************************/ bool Ringbuf_Put( RING_BUFFER *b, // ring buffer structure char *data_element) // one element to add to the ring { bool status = false; // return value unsigned offset = 0; // offset into array of data char *ring_data = NULL; // used to help point ring data unsigned i; // loop counter if (b && data_element) { // limit the amount of data that we accept if (b->count < b->element_count) { offset = b->head + b->count; if (offset >= b->element_count) offset -= b->element_count; ring_data = b->data + offset * b->element_size; for(i = 0; i < b->element_size; i++) { ring_data[i] = data_element[i]; } b->count++; status = true; } } return status; } /**************************************************************************** * DESCRIPTION: Configures the ring buffer * RETURN: none * ALGORITHM: none * NOTES: none *****************************************************************************/ void Ringbuf_Init( RING_BUFFER *b, // ring buffer structure char *data, // data block or array of data unsigned element_size, // size of one element in the data block unsigned element_count) // number of elements in the data block { b->head = 0; b->count = 0; b->data = data; b->element_size = element_size; b->element_count = element_count; return; } #ifdef TEST #include #include #include "ctest.h" // test the FIFO #define RING_BUFFER_DATA_SIZE 5 #define RING_BUFFER_SIZE 16 void testRingBuf(Test* pTest) { RING_BUFFER test_buffer; char data_store[RING_BUFFER_DATA_SIZE * RING_BUFFER_SIZE]; char data[RING_BUFFER_DATA_SIZE]; char *test_data; unsigned index; unsigned data_index; unsigned count; unsigned dummy; bool status; Ringbuf_Init(&test_buffer,data_store,RING_BUFFER_DATA_SIZE,RING_BUFFER_SIZE); ct_test(pTest,Ringbuf_Empty(&test_buffer)); for (data_index = 0; data_index < RING_BUFFER_DATA_SIZE; data_index++) { data[data_index] = data_index; } status = Ringbuf_Put(&test_buffer, data); ct_test(pTest,status == true); ct_test(pTest,!Ringbuf_Empty(&test_buffer)); test_data = Ringbuf_Get_Front(&test_buffer); for (data_index = 0; data_index < RING_BUFFER_DATA_SIZE; data_index++) { ct_test(pTest,test_data[data_index] == data[data_index]); } ct_test(pTest,!Ringbuf_Empty(&test_buffer)); test_data = Ringbuf_Pop_Front(&test_buffer); for (data_index = 0; data_index < RING_BUFFER_DATA_SIZE; data_index++) { ct_test(pTest,test_data[data_index] == data[data_index]); } ct_test(pTest,Ringbuf_Empty(&test_buffer)); // fill to max for (index = 0; index < RING_BUFFER_SIZE; index++) { for (data_index = 0; data_index < RING_BUFFER_DATA_SIZE; data_index++) { data[data_index] = index; } status = Ringbuf_Put(&test_buffer, data); ct_test(pTest,status == true); ct_test(pTest,!Ringbuf_Empty(&test_buffer)); } // verify actions on full buffer for (index = 0; index < RING_BUFFER_SIZE; index++) { for (data_index = 0; data_index < RING_BUFFER_DATA_SIZE; data_index++) { data[data_index] = index; } status = Ringbuf_Put(&test_buffer, data); ct_test(pTest,status == false); ct_test(pTest,!Ringbuf_Empty(&test_buffer)); } // check buffer full for (index = 0; index < RING_BUFFER_SIZE; index++) { test_data = Ringbuf_Get_Front(&test_buffer); for (data_index = 0; data_index < RING_BUFFER_DATA_SIZE; data_index++) { ct_test(pTest,test_data[data_index] == index); } test_data = Ringbuf_Pop_Front(&test_buffer); for (data_index = 0; data_index < RING_BUFFER_DATA_SIZE; data_index++) { ct_test(pTest,test_data[data_index] == index); } } ct_test(pTest,Ringbuf_Empty(&test_buffer)); // test the ring around the buffer for (index = 0; index < RING_BUFFER_SIZE; index++) { for (count = 1; count < 4; count++) { dummy = index * count; for (data_index = 0; data_index < RING_BUFFER_DATA_SIZE; data_index++) { data[data_index] = dummy; } status = Ringbuf_Put(&test_buffer, data); ct_test(pTest,status == true); } for (count = 1; count < 4; count++) { dummy = index * count; test_data = Ringbuf_Get_Front(&test_buffer); for (data_index = 0; data_index < RING_BUFFER_DATA_SIZE; data_index++) { ct_test(pTest,test_data[data_index] == dummy); } test_data = Ringbuf_Pop_Front(&test_buffer); for (data_index = 0; data_index < RING_BUFFER_DATA_SIZE; data_index++) { ct_test(pTest,test_data[data_index] == dummy); } } } ct_test(pTest,Ringbuf_Empty(&test_buffer)); return; } #ifdef TEST_RINGBUF int main(void) { Test *pTest; bool rc; pTest = ct_create("ringbuf", NULL); /* individual tests */ rc = ct_addTestFunction(pTest, testRingBuf); assert(rc); ct_setStream(pTest, stdout); ct_run(pTest); (void)ct_report(pTest); ct_destroy(pTest); return 0; } #endif #endif