Jeroen Lodder
Multi purpose buffer module.
Multipurpose ringbuffer
Since there weren't any ringbuffers available on the internet optimized for 32-Bit ARM operation without unix-calls and dynamic memory... I created one.
This module is a fixed ringbuffer, it does not allocate any memory, it can work as FIFO or LIFO or any other exotic mode depending on your imagination. With a fixed 32Bit element size it is optimized for 32 bit arm processors. Any smaller value will have overhead, any larger value will require a double entry. (not recommended)
I hope you can use it.
Information
This is not a C++ class, it is a C Module. It does work object oriented, however you cannot work on the object, you work with the object.
xIFO.cpp
- Committer:
- jeroen3
- Date:
- 2014-04-04
- Revision:
- 2:6013f6d867e5
- Parent:
- xIFO.c@ 1:5f59aa9b86ed
File content as of revision 2:6013f6d867e5:
/**
* @file xifo.c
* @brief xifo circular buffer with <t>/8/16/32/64 bit elements
* @details xifo supplies object oriented circular buffer with 8 bit size elements. \n
* To use either as FIFO (First In First Out) or as FILO (First In Last Out)
* You might want to rename this file is you are using a C compiler.
*
* @Author Jeroen Lodder
* @Date March 2014
* @version 3
*
* Copyright (c) 2014 Jeroen Lodder
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*
* @{
*/
#include "xIFO.h"
#if xIFO_USE_64BIT == TRUE
/**
* @brief Initialize buffer object structure.
*
* @note Does not clear memory pool.
*
* @param[in] c Pointer to @p xifo64_t object used for configuration.
* @param[in] s Number of elements buffer can hold (size).
* @param[in] sp Start of pre-allocated memory pool.
*/
void xifo64_init(xifo64_t *c, uint32_t s, uint64_t *sp){
c->startpool = sp;
c->size = s;
c->endpool = &sp[--s];
c->full = 0;
c->count = 0;
c->read = sp;
c->write = sp;
}
/**
* @brief Clear buffer memory pool
*
* @note Must be used on initialised buffer object.
*
* @param[in] c Pointer to @p xifo64_t object.
*/
void xifo64_clear(xifo64_t *c){
register uint64_t *ptemp = c->startpool;
register uint32_t i = c->size;
while(i--){
*ptemp++ = 0;
}
}
/**
* @brief Read from buffer (lr) Least Recent oriented (fifo)
*
* @note Buffer state will be preserved
*
* @warning Consider this opertaion as atomic!
*
* @details Read n elements from the oldest element to the most recent.
* As for index[0] the least recently added element is returned.
* And for index[count] the most recent element is returned.
* This makes it possible to peek in fifo.
*
* @param[in] c Pointer to @p xifo64_t used for configuration.
* @param[in] index Index relative from least recent
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint64_t xifo64_read_lr(xifo64_t *c, uint32_t index){
register uint64_t *ptemp;
/* Verify there is valid data to read */
if(index >= c->count){
return 0; /* Nothing to read there */
}
/* Calculate index of oldest element */
index = (c->count-1) - index;
/* Set pointer */
ptemp = (c->read) - index;
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read most recent */
return *ptemp;
}
/**
* @brief Read from buffer (mr) Most Recent oriented (filo)
*
* @note Buffer state will be preserved
*
* @warning Consider this opertaion as atomic!
*
* @details Read n elements back in time.
* As for index[0] the most recently added element is returned.
* And for index[count] the oldest element is returned.
* This makes it possible to keep history. For DSP application.
*
* @param[in] c Pointer to @p xifo64_t used for configuration.
* @param[in] index Index relative from most recent
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint64_t xifo64_read_mr(xifo64_t *c, uint32_t index){
register uint64_t *ptemp;
/* Verify there is valid data to read */
if(index >= c->count){
return 0; /* Nothing to read there */
}
/* Set pointer */
ptemp = (c->read) - index;
/* Validate pointer */
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read most recent */
return *ptemp;
}
/**
* @brief Pop (mr) most recent from buffer (filo)
*
* @note Buffer state will be altered
*
* @warning Consider this opertaion as atomic!
*
* @details Read and remove the most recently added from the buffer.
* Using this results in a stack type of buffer.
*
* @param[in] c Pointer to @p xifo64_t used for configuration.
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint64_t xifo64_pop_mr(xifo64_t *c){
register uint64_t temp;
/* Verify there is valid data read */
if(c->count == 0){
return 0; /* Nothing to read there */
}
/* Read */
temp = *c->read;
/* Empty */
*c->read = 0;
/* Most recent element read, return write pointer */
c->write = c->read;
/* Decrement read pointer */
c->read--;
/* Validate pointer */
if( c->read < c->startpool ){
/* Exceeded pool boundaries */
c->read = c->endpool;
}
/* Reduce count */
c->count--;
if(c->count < c->size)
c->full = 0;
return temp;
}
/**
* @brief Pop (lr) least recent from buffer (fifo)
*
* @note Buffer state will be altered
*
* @warning Consider this opertaion as atomic!
*
* @details Read and remove the least recently added from the buffer.
* Using this results in a fifo type of buffer.
*
* @param[in] c Pointer to @p xifo64_t used for configuration.
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint64_t xifo64_pop_lr(xifo64_t *c){
register uint64_t *ptemp;
register uint64_t temp;
/* Verify there is valid data read */
if(c->count == 0){
return 0; /* Nothing to read there */
}
/* Derive least recent buffer element */
ptemp = (c->read+1) - c->count;
/* Validate pointer */
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read oldest buffer element */
/* Read to temp register */
temp = *ptemp;
/* Empty buffer element */
*ptemp = 0;
/* Reduce count */
c->count--;
/* Check full flag */
if(c->count < c->size)
c->full = 0;
return temp;
}
/**
* @brief Write to buffer
*
* @note Readpointer is automatically set to the last added element.
*
* @warning Consider this opertaion as atomic!
*
* @details Adds a value to the buffer.
* Automatically overwrites oldest elements when full.
*
* @param[in] c Pointer to @p xifo64_t used for configuration.
* @param[in] data Data to add to buffer
*
* @return Number of free buffer elements
*/
uint32_t xifo64_write(xifo64_t *c, uint64_t data){
/* Write data */
*c->write = data;
/* Update read pointer to most recent element */
c->read = c->write;
/* Write pointer increment */
c->write++;
/* Validate pointer */
if( c->write > c->endpool){
/* We exceeded pool boundaries */
c->write = c->startpool;
}
/* Update count */
c->count++;
/* Verify full */
if( c->count >= c->size ){
c->full = 1;
c->count = c->size;
}
/* return free elements count */
return c->size - c->count;
}
/**
* @brief Get buffer size
*
* @param[in] c Pointer to @p xifo64_t used for configuration.
*
* @return Size of memory pool in elements
*/
uint32_t xifo64_get_size(xifo64_t *c){
return c->size;
}
/**
* @brief Get number of used elements
*
* @param[in] c Pointer to @p xifo64_t used for configuration.
*
* @return Number of used buffer elements
*/
uint32_t xifo64_get_used(xifo64_t *c){
return c->count;
}
/**
* @brief Get number of free elements
*
* @param[in] c Pointer to @p xifo64_t used for configuration.
*
* @return Number of free elements
*/
uint32_t xifo64_get_free(xifo64_t *c){
return c->size - c->count;
}
/**
* @brief Get full flag
*
* @param[in] c Pointer to @p xifo64_t used for configuration.
*
* @return 1 if full
*/
uint32_t xifo64_get_full(xifo64_t *c){
return c->full;
}
/** @} */
#endif
#if xIFO_USE_32BIT == TRUE
/**
* @brief Initialize buffer object structure.
*
* @note Does not clear memory pool.
*
* @param[in] c Pointer to @p xifo32_t object used for configuration.
* @param[in] s Number of elements buffer can hold (size).
* @param[in] sp Start of pre-allocated memory pool.
*/
void xifo32_init(xifo32_t *c, uint32_t s, uint32_t *sp){
c->startpool = sp;
c->size = s;
c->endpool = &sp[--s];
c->full = 0;
c->count = 0;
c->read = sp;
c->write = sp;
}
/**
* @brief Clear buffer memory pool
*
* @note Must be used on initialised buffer object.
*
* @param[in] c Pointer to @p xifo32_t object.
*/
void xifo32_clear(xifo32_t *c){
register uint32_t *ptemp = c->startpool;
register uint32_t i = c->size;
while(i--){
*ptemp++ = 0;
}
}
/**
* @brief Read from buffer (lr) Least Recent oriented (fifo)
*
* @note Buffer state will be preserved
*
* @warning Consider this opertaion as atomic!
*
* @details Read n elements from the oldest element to the most recent.
* As for index[0] the least recently added element is returned.
* And for index[count] the most recent element is returned.
* This makes it possible to peek in fifo.
*
* @param[in] c Pointer to @p xifo32_t used for configuration.
* @param[in] index Index relative from least recent
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint32_t xifo32_read_lr(xifo32_t *c, uint32_t index){
register uint32_t *ptemp;
/* Verify there is valid data to read */
if(index >= c->count){
return 0; /* Nothing to read there */
}
/* Calculate index of oldest element */
index = (c->count-1) - index;
/* Set pointer */
ptemp = (c->read) - index;
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read most recent */
return *ptemp;
}
/**
* @brief Read from buffer (mr) Most Recent oriented (filo)
*
* @note Buffer state will be preserved
*
* @warning Consider this opertaion as atomic!
*
* @details Read n elements back in time.
* As for index[0] the most recently added element is returned.
* And for index[count] the oldest element is returned.
* This makes it possible to keep history. For DSP application.
*
* @param[in] c Pointer to @p xifo32_t used for configuration.
* @param[in] index Index relative from most recent
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint32_t xifo32_read_mr(xifo32_t *c, uint32_t index){
register uint32_t *ptemp;
/* Verify there is valid data to read */
if(index >= c->count){
return 0; /* Nothing to read there */
}
/* Set pointer */
ptemp = (c->read) - index;
/* Validate pointer */
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read most recent */
return *ptemp;
}
/**
* @brief Pop (mr) most recent from buffer (filo)
*
* @note Buffer state will be altered
*
* @warning Consider this opertaion as atomic!
*
* @details Read and remove the most recently added from the buffer.
* Using this results in a stack type of buffer.
*
* @param[in] c Pointer to @p xifo32_t used for configuration.
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint32_t xifo32_pop_mr(xifo32_t *c){
register uint32_t temp;
/* Verify there is valid data read */
if(c->count == 0){
return 0; /* Nothing to read there */
}
/* Read */
temp = *c->read;
/* Empty */
*c->read = 0;
/* Most recent element read, return write pointer */
c->write = c->read;
/* Decrement read pointer */
c->read--;
/* Validate pointer */
if( c->read < c->startpool ){
/* Exceeded pool boundaries */
c->read = c->endpool;
}
/* Reduce count */
c->count--;
if(c->count < c->size)
c->full = 0;
return temp;
}
/**
* @brief Pop (lr) least recent from buffer (fifo)
*
* @note Buffer state will be altered
*
* @warning Consider this opertaion as atomic!
*
* @details Read and remove the least recently added from the buffer.
* Using this results in a fifo type of buffer.
*
* @param[in] c Pointer to @p xifo32_t used for configuration.
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint32_t xifo32_pop_lr(xifo32_t *c){
register uint32_t *ptemp;
register uint32_t temp;
/* Verify there is valid data read */
if(c->count == 0){
return 0; /* Nothing to read there */
}
/* Derive least recent buffer element */
ptemp = (c->read+1) - c->count;
/* Validate pointer */
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read oldest buffer element */
/* Read to temp register */
temp = *ptemp;
/* Empty buffer element */
*ptemp = 0;
/* Reduce count */
c->count--;
/* Check full flag */
if(c->count < c->size)
c->full = 0;
return temp;
}
/**
* @brief Write to buffer
*
* @note Readpointer is automatically set to the last added element.
*
* @warning Consider this opertaion as atomic!
*
* @details Adds a value to the buffer.
* Automatically overwrites oldest elements when full.
*
* @param[in] c Pointer to @p xifo32_t used for configuration.
* @param[in] data Data to add to buffer
*
* @return Number of free buffer elements
*/
uint32_t xifo32_write(xifo32_t *c, uint32_t data){
/* Write data */
*c->write = data;
/* Update read pointer to most recent element */
c->read = c->write;
/* Write pointer increment */
c->write++;
/* Validate pointer */
if( c->write > c->endpool){
/* We exceeded pool boundaries */
c->write = c->startpool;
}
/* Update count */
c->count++;
/* Verify full */
if( c->count >= c->size ){
c->full = 1;
c->count = c->size;
}
/* return free elements count */
return c->size - c->count;
}
/**
* @brief Get buffer size
*
* @param[in] c Pointer to @p xifo32_t used for configuration.
*
* @return Size of memory pool in elements
*/
uint32_t xifo32_get_size(xifo32_t *c){
return c->size;
}
/**
* @brief Get number of used elements
*
* @param[in] c Pointer to @p xifo32_t used for configuration.
*
* @return Number of used buffer elements
*/
uint32_t xifo32_get_used(xifo32_t *c){
return c->count;
}
/**
* @brief Get number of free elements
*
* @param[in] c Pointer to @p xifo32_t used for configuration.
*
* @return Number of free elements
*/
uint32_t xifo32_get_free(xifo32_t *c){
return c->size - c->count;
}
/**
* @brief Get full flag
*
* @param[in] c Pointer to @p xifo32_t used for configuration.
*
* @return 1 if full
*/
uint32_t xifo32_get_full(xifo32_t *c){
return c->full;
}
/** @} */
#endif
#if xIFO_USE_16BIT == TRUE
/**
* @brief Initialize buffer object structure.
*
* @note Does not clear memory pool.
*
* @param[in] c Pointer to @p xifo16_t object used for configuration.
* @param[in] s Number of elements buffer can hold (size).
* @param[in] sp Start of pre-allocated memory pool.
*/
void xifo16_init(xifo16_t *c, uint32_t s, uint16_t *sp){
c->startpool = sp;
c->size = s;
c->endpool = &sp[--s];
c->full = 0;
c->count = 0;
c->read = sp;
c->write = sp;
}
/**
* @brief Clear buffer memory pool
*
* @note Must be used on initialised buffer object.
*
* @param[in] c Pointer to @p xifo16_t object.
*/
void xifo16_clear(xifo16_t *c){
register uint16_t *ptemp = c->startpool;
register uint32_t i = c->size;
while(i--){
*ptemp++ = 0;
}
}
/**
* @brief Read from buffer (lr) Least Recent oriented (fifo)
*
* @note Buffer state will be preserved
*
* @warning Consider this opertaion as atomic!
*
* @details Read n elements from the oldest element to the most recent.
* As for index[0] the least recently added element is returned.
* And for index[count] the most recent element is returned.
* This makes it possible to peek in fifo.
*
* @param[in] c Pointer to @p xifo16_t used for configuration.
* @param[in] index Index relative from least recent
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint16_t xifo16_read_lr(xifo16_t *c, uint32_t index){
register uint16_t *ptemp;
/* Verify there is valid data to read */
if(index >= c->count){
return 0; /* Nothing to read there */
}
/* Calculate index of oldest element */
index = (c->count-1) - index;
/* Set pointer */
ptemp = (c->read) - index;
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read most recent */
return *ptemp;
}
/**
* @brief Read from buffer (mr) Most Recent oriented (filo)
*
* @note Buffer state will be preserved
*
* @warning Consider this opertaion as atomic!
*
* @details Read n elements back in time.
* As for index[0] the most recently added element is returned.
* And for index[count] the oldest element is returned.
* This makes it possible to keep history. For DSP application.
*
* @param[in] c Pointer to @p xifo16_t used for configuration.
* @param[in] index Index relative from most recent
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint16_t xifo16_read_mr(xifo16_t *c, uint32_t index){
register uint16_t *ptemp;
/* Verify there is valid data to read */
if(index >= c->count){
return 0; /* Nothing to read there */
}
/* Set pointer */
ptemp = (c->read) - index;
/* Validate pointer */
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read most recent */
return *ptemp;
}
/**
* @brief Pop (mr) most recent from buffer (filo)
*
* @note Buffer state will be altered
*
* @warning Consider this opertaion as atomic!
*
* @details Read and remove the most recently added from the buffer.
* Using this results in a stack type of buffer.
*
* @param[in] c Pointer to @p xifo16_t used for configuration.
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint16_t xifo16_pop_mr(xifo16_t *c){
register uint16_t temp;
/* Verify there is valid data read */
if(c->count == 0){
return 0; /* Nothing to read there */
}
/* Read */
temp = *c->read;
/* Empty */
*c->read = 0;
/* Most recent element read, return write pointer */
c->write = c->read;
/* Decrement read pointer */
c->read--;
/* Validate pointer */
if( c->read < c->startpool ){
/* Exceeded pool boundaries */
c->read = c->endpool;
}
/* Reduce count */
c->count--;
if(c->count < c->size)
c->full = 0;
return temp;
}
/**
* @brief Pop (lr) least recent from buffer (fifo)
*
* @note Buffer state will be altered
*
* @warning Consider this opertaion as atomic!
*
* @details Read and remove the least recently added from the buffer.
* Using this results in a fifo type of buffer.
*
* @param[in] c Pointer to @p xifo16_t used for configuration.
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint16_t xifo16_pop_lr(xifo16_t *c){
register uint16_t *ptemp;
register uint16_t temp;
/* Verify there is valid data read */
if(c->count == 0){
return 0; /* Nothing to read there */
}
/* Derive least recent buffer element */
ptemp = (c->read+1) - c->count;
/* Validate pointer */
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read oldest buffer element */
/* Read to temp register */
temp = *ptemp;
/* Empty buffer element */
*ptemp = 0;
/* Reduce count */
c->count--;
/* Check full flag */
if(c->count < c->size)
c->full = 0;
return temp;
}
/**
* @brief Write to buffer
*
* @note Readpointer is automatically set to the last added element.
*
* @warning Consider this opertaion as atomic!
*
* @details Adds a value to the buffer.
* Automatically overwrites oldest elements when full.
*
* @param[in] c Pointer to @p xifo16_t used for configuration.
* @param[in] data Data to add to buffer
*
* @return Number of free buffer elements
*/
uint32_t xifo16_write(xifo16_t *c, uint16_t data){
/* Write data */
*c->write = data;
/* Update read pointer to most recent element */
c->read = c->write;
/* Write pointer increment */
c->write++;
/* Validate pointer */
if( c->write > c->endpool){
/* We exceeded pool boundaries */
c->write = c->startpool;
}
/* Update count */
c->count++;
/* Verify full */
if( c->count >= c->size ){
c->full = 1;
c->count = c->size;
}
/* return free elements count */
return c->size - c->count;
}
/**
* @brief Get buffer size
*
* @param[in] c Pointer to @p xifo16_t used for configuration.
*
* @return Size of memory pool in elements
*/
uint32_t xifo16_get_size(xifo16_t *c){
return c->size;
}
/**
* @brief Get number of used elements
*
* @param[in] c Pointer to @p xifo16_t used for configuration.
*
* @return Number of used buffer elements
*/
uint32_t xifo16_get_used(xifo16_t *c){
return c->count;
}
/**
* @brief Get number of free elements
*
* @param[in] c Pointer to @p xifo16_t used for configuration.
*
* @return Number of free elements
*/
uint32_t xifo16_get_free(xifo16_t *c){
return c->size - c->count;
}
/**
* @brief Get full flag
*
* @param[in] c Pointer to @p xifo16_t used for configuration.
*
* @return 1 if full
*/
uint32_t xifo16_get_full(xifo16_t *c){
return c->full;
}
/** @} */
#endif
#if xIFO_USE_8BIT == TRUE
/**
* @brief Initialize buffer object structure.
*
* @note Does not clear memory pool.
*
* @param[in] c Pointer to @p xifo8_t object used for configuration.
* @param[in] s Number of elements buffer can hold (size).
* @param[in] sp Start of pre-allocated memory pool.
*/
void xifo8_init(xifo8_t *c, uint32_t s, uint8_t *sp){
c->startpool = sp;
c->size = s;
c->endpool = &sp[--s];
c->full = 0;
c->count = 0;
c->read = sp;
c->write = sp;
}
/**
* @brief Clear buffer memory pool
*
* @note Must be used on initialised buffer object.
*
* @param[in] c Pointer to @p xifo8_t object.
*/
void xifo8_clear(xifo8_t *c){
register uint8_t *ptemp = c->startpool;
register uint32_t i = c->size;
while(i--){
*ptemp++ = 0;
}
}
/**
* @brief Read from buffer (lr) Least Recent oriented (fifo)
*
* @note Buffer state will be preserved
*
* @warning Consider this opertaion as atomic!
*
* @details Read n elements from the oldest element to the most recent.
* As for index[0] the least recently added element is returned.
* And for index[count] the most recent element is returned.
* This makes it possible to peek in fifo.
*
* @param[in] c Pointer to @p xifo8_t used for configuration.
* @param[in] index Index relative from least recent
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint8_t xifo8_read_lr(xifo8_t *c, uint32_t index){
register uint8_t *ptemp;
/* Verify there is valid data to read */
if(index >= c->count){
return 0; /* Nothing to read there */
}
/* Calculate index of oldest element */
index = (c->count-1) - index;
/* Set pointer */
ptemp = (c->read) - index;
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read most recent */
return *ptemp;
}
/**
* @brief Read from buffer (mr) Most Recent oriented (filo)
*
* @note Buffer state will be preserved
*
* @warning Consider this opertaion as atomic!
*
* @details Read n elements back in time.
* As for index[0] the most recently added element is returned.
* And for index[count] the oldest element is returned.
* This makes it possible to keep history. For DSP application.
*
* @param[in] c Pointer to @p xifo8_t used for configuration.
* @param[in] index Index relative from most recent
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint8_t xifo8_read_mr(xifo8_t *c, uint32_t index){
register uint8_t *ptemp;
/* Verify there is valid data to read */
if(index >= c->count){
return 0; /* Nothing to read there */
}
/* Set pointer */
ptemp = (c->read) - index;
/* Validate pointer */
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read most recent */
return *ptemp;
}
/**
* @brief Pop (mr) most recent from buffer (filo)
*
* @note Buffer state will be altered
*
* @warning Consider this opertaion as atomic!
*
* @details Read and remove the most recently added from the buffer.
* Using this results in a stack type of buffer.
*
* @param[in] c Pointer to @p xifo8_t used for configuration.
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint8_t xifo8_pop_mr(xifo8_t *c){
register uint8_t temp;
/* Verify there is valid data read */
if(c->count == 0){
return 0; /* Nothing to read there */
}
/* Read */
temp = *c->read;
/* Empty */
*c->read = 0;
/* Most recent element read, return write pointer */
c->write = c->read;
/* Decrement read pointer */
c->read--;
/* Validate pointer */
if( c->read < c->startpool ){
/* Exceeded pool boundaries */
c->read = c->endpool;
}
/* Reduce count */
c->count--;
if(c->count < c->size)
c->full = 0;
return temp;
}
/**
* @brief Pop (lr) least recent from buffer (fifo)
*
* @note Buffer state will be altered
*
* @warning Consider this opertaion as atomic!
*
* @details Read and remove the least recently added from the buffer.
* Using this results in a fifo type of buffer.
*
* @param[in] c Pointer to @p xifo8_t used for configuration.
*
* @return Contents of element or 0 if failed (element can hold 0)
*/
uint8_t xifo8_pop_lr(xifo8_t *c){
register uint8_t *ptemp;
register uint8_t temp;
/* Verify there is valid data read */
if(c->count == 0){
return 0; /* Nothing to read there */
}
/* Derive least recent buffer element */
ptemp = (c->read+1) - c->count;
/* Validate pointer */
if(ptemp < c->startpool){
/* Exceeded pool boundaries */
/* Calculate overshoot (startpool - indexptr) and subtract from end */
/* Since one element of overshoot results in end - 1 you would miss the last value */
ptemp = (c->endpool+1) - (c->startpool - ptemp);
}
/* Read oldest buffer element */
/* Read to temp register */
temp = *ptemp;
/* Empty buffer element */
*ptemp = 0;
/* Reduce count */
c->count--;
/* Check full flag */
if(c->count < c->size)
c->full = 0;
return temp;
}
/**
* @brief Write to buffer
*
* @note Readpointer is automatically set to the last added element.
*
* @warning Consider this opertaion as atomic!
*
* @details Adds a value to the buffer.
* Automatically overwrites oldest elements when full.
*
* @param[in] c Pointer to @p xifo8_t used for configuration.
* @param[in] data Data to add to buffer
*
* @return Number of free buffer elements
*/
uint32_t xifo8_write(xifo8_t *c, uint8_t data){
/* Write data */
*c->write = data;
/* Update read pointer to most recent element */
c->read = c->write;
/* Write pointer increment */
c->write++;
/* Validate pointer */
if( c->write > c->endpool){
/* We exceeded pool boundaries */
c->write = c->startpool;
}
/* Update count */
c->count++;
/* Verify full */
if( c->count >= c->size ){
c->full = 1;
c->count = c->size;
}
/* return free elements count */
return c->size - c->count;
}
/**
* @brief Get buffer size
*
* @param[in] c Pointer to @p xifo8_t used for configuration.
*
* @return Size of memory pool in elements
*/
uint32_t xifo8_get_size(xifo8_t *c){
return c->size;
}
/**
* @brief Get number of used elements
*
* @param[in] c Pointer to @p xifo8_t used for configuration.
*
* @return Number of used buffer elements
*/
uint32_t xifo8_get_used(xifo8_t *c){
return c->count;
}
/**
* @brief Get number of free elements
*
* @param[in] c Pointer to @p xifo8_t used for configuration.
*
* @return Number of free elements
*/
uint32_t xifo8_get_free(xifo8_t *c){
return c->size - c->count;
}
/**
* @brief Get full flag
*
* @param[in] c Pointer to @p xifo8_t used for configuration.
*
* @return 1 if full
*/
uint32_t xifo8_get_full(xifo8_t *c){
return c->full;
}
/** @} */
#endif
/** @} */