Rob Meades
Support for LISA-N101
Fork of
C027_Support
by 
u-blox
This is a variant of the C027 driver code for the C027N version, i.e. the one with the Neul/Huawei/u-blox Cellular Internet of Things module on board. The AT command interface for this module is entirely different to the AT interface for the other u-blox modules, hence this fork of the driver. Work is underway to rearchitect the original C027 driver so that a merge can be done.
Pipe.h
- Committer:
- RobMeades
- Date:
- 2015-06-17
- Revision:
- 127:4df82b52f834
- Parent:
- 101:edfeb8af206e
File content as of revision 127:4df82b52f834:
#pragma once
/** pipe, this class implements a buffered pipe that can be savely
written and read between two context. E.g. Written from a task
and read from a interrupt.
*/
template <class T>
class Pipe
{
public:
/* Constructor
\param n size of the pipe/buffer
\param b optional buffer that should be used.
if NULL the constructor will allocate a buffer of size n.
*/
Pipe(int n, T* b = NULL)
{
_a = b ? NULL : n ? new T[n] : NULL;
_r = 0;
_w = 0;
_b = b ? b : _a;
_s = n;
}
/** Destructor
frees a allocated buffer.
*/
~Pipe(void)
{
if (_a)
delete [] _a;
}
/* This function can be used during debugging to hexdump the
content of a buffer to the stdout.
*/
void dump(void)
{
int o = _r;
printf("pipe: %d/%d ", size(), _s);
while (o != _w) {
T t = _b[o];
printf("%0*X", sizeof(T)*2, t);
o = _inc(o);
}
printf("\n");
}
// writing thread/context API
//-------------------------------------------------------------
/** Check if buffer is writeable (=not full)
\return true if writeable
*/
bool writeable(void)
{
return free() > 0;
}
/** Return the number of free elements in the buffer
\return the number of free elements
*/
int free(void)
{
int s = _r - _w;
if (s <= 0)
s += _s;
return s - 1;
}
/* Add a single element to the buffer. (blocking)
\param c the element to add.
\return c
*/
T putc(T c)
{
int i = _w;
int j = i;
i = _inc(i);
while (i == _r) // = !writeable()
/* nothing / just wait */;
_b[j] = c;
_w = i;
return c;
}
/* Add a buffer of elements to the buffer.
\param p the elements to add
\param n the number elements to add from p
\param t set to true if blocking, false otherwise
\return number elements added
*/
int put(const T* p, int n, bool t = false)
{
int c = n;
while (c)
{
int f;
for (;;) // wait for space
{
f = free();
if (f > 0) break; // data avail
if (!t) return n - c; // no more space and not blocking
/* nothing / just wait */;
}
// check free space
if (c < f) f = c;
int w = _w;
int m = _s - w;
// check wrap
if (f > m) f = m;
memcpy(&_b[w], p, f);
_w = _inc(w, f);
c -= f;
p += f;
}
return n - c;
}
// reading thread/context API
// --------------------------------------------------------
/** Check if there are any emelemnt available (readble / not empty)
\return true if readable/not empty
*/
bool readable(void)
{
return (_r != _w);
}
/** Get the number of values available in the buffer
return the number of element available
*/
int size(void)
{
int s = _w - _r;
if (s < 0)
s += _s;
return s;
}
/** get a single value from buffered pipe (this function will block if no values available)
\return the element extracted
*/
T getc(void)
{
int r = _r;
while (r == _w) // = !readable()
/* nothing / just wait */;
T t = _b[r];
_r = _inc(r);
return t;
}
/*! get elements from the buffered pipe
\param p the elements extracted
\param n the maximum number elements to extract
\param t set to true if blocking, false otherwise
\return number elements extracted
*/
int get(T* p, int n, bool t = false)
{
int c = n;
while (c)
{
int f;
for (;;) // wait for data
{
f = size();
if (f) break; // free space
if (!t) return n - c; // no space and not blocking
/* nothing / just wait */;
}
// check available data
if (c < f) f = c;
int r = _r;
int m = _s - r;
// check wrap
if (f > m) f = m;
memcpy(p, &_b[r], f);
_r = _inc(r, f);
c -= f;
p += f;
}
return n - c;
}
// the following functions are useful if you like to inspect
// or parse the buffer in the reading thread/context
// --------------------------------------------------------
/** set the parsing index and return the number of available
elments starting this position.
\param ix the index to set.
\return the number of elements starting at this position
*/
int set(int ix)
{
int sz = size();
ix = (ix > sz) ? sz : ix;
_o = _inc(_r, ix);
return sz - ix;
}
/** get the next element from parsing position and increment parsing index
\return the extracted element.
*/
T next(void)
{
int o = _o;
T t = _b[o];
_o = _inc(o);
return t;
}
/** commit the index, mark the current parsing index as consumed data.
*/
void done(void)
{
_r = _o;
}
private:
/** increment the index
\param i index to increment
\param n the step to increment
\return the incremented index.
*/
inline int _inc(int i, int n = 1)
{
i += n;
if (i >= _s)
i -= _s;
return i;
}
T* _b; //!< buffer
T* _a; //!< allocated buffer
int _s; //!< size of buffer (s - 1) elements can be stored
volatile int _w; //!< write index
volatile int _r; //!< read index
int _o; //!< offest index used by parsing functions
};