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symposium.h
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symposium.h
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#ifndef __SYMPOSIUM__H
#define __SYMPOSIUM__H
/**
@file symposium.h
@brief An implementation of Dining Philosophers.
The Dining Philisophers are sitting around a Symposium
roundtable. Each philosopher comes to the table, cycles
between thinking and eating a number of times, and leaves the
table.
However,
- in order to eat she needs to hold a fork in each hand, and
- there is only one fork between two philosophers.
Therefore, a philosopher may wait hungry for forks to become
available.
In our simulation, a philosopher is a thread. The symposium is
implemented as a monitor, with each philosopher waiting at
their own condition variable.
During each thinking or eating period, a philosopher computes
Fibonacci numbers using an exponentially
expensive recursion:
\f[ F(n+2) = F(n+1) + F(n) \f]
with \f$F(0) = 0\f$ and \f$F(1)=1\f$.
The complexity of this recursion is \f$ O( \phi^n )\f$ where
\f$\phi=\frac{1+\sqrt{5}}{2}\approx 1.618\f$ is the __golden ratio__.
For each thinking session, an integer \f$n\f$ is drawn uniformly at random
from the set \f$ [f_\text{min}, f_\text{max}] \f$.
Overall, a symposium is specified by four numbers:
- @c N, the number of philosophers
- `bites`, the number of times each of them eats
- \f$f_\text{min}, f_\text{max}\f$ which determine
the time of each thinking and eating period.
In order to make symposia with a large number of philosophers or number of bites,
we can compute suitable values of \f$f_\text{min}, f_\text{max}\f$. We use the
following simple formulas:
\f[ f_\text{min} = F_\text{BASE} - \log_\phi( 2*N*\text{bites} ) \f]
and
\f[ f_\text{max} = f_\text{min} + F_\text{GAP}. \f]
The constants \f$F_\text{BASE}\f$ and \f$F_\text{GAP}\f$ are defined in the source
code.
@see FBASE
@see FGAP
*/
#include "tinyos.h"
/** @brief The default for constant \f$F_\text{BASE}\f$ */
#define FBASE 35
/** @brief The default for constant \f$F_\text{GAP}\f$ */
#define FGAP 10
/** @brief Compute the n-th Fibonacci number recursively.
The purpose of this function is to burn CPU cycles. Its complexity
is \f$ O( \phi^n )\f$ where
\f$\phi=\frac{1+\sqrt{5}}{2}\approx 1.618\f$ is the golden ratio.
@param n the index of the Fibonacci number
@returns the n-th Fibonacci number
*/
extern unsigned int fibo(unsigned int n);
/** @brief A philosopher's state. */
typedef enum { NOTHERE=0, THINKING, HUNGRY, EATING } PHIL;
/** @brief A symposium definition.
The four numbers defining a symposium.
*/
typedef struct {
int N; /**< Number of philosophers */
int bites; /**< Number of bites each philosopher takes. */
int fmin, fmax; /**< Values used by the Fibbonacci routines */
} symposium_t;
/** @brief Adjust a symposium's duration.
This function computes \f$f_\text{min}, f_\text{max}\f$ based
on the values
\f[ F_\text{BASE} = \text{FBASE}+\text{dBASE} \f]
and
\f[ F_\text{GAP} = \text{FGAP}+\text{dGAP}. \f]
The computed values are stored in @c table.
@param table the symposium table whose \f$f\f$-values are computed.
@param dBASE added to @ref FBASE
@param dGAP added to @ref FGAP
@see FBASE
@see FGAP
*/
void adjust_symposium(symposium_t* table, int dBASE, int dGAP);
/** @brief A symposium monitor.
Such an object must be shared between all philosopher
threads/processes.
*/
typedef struct {
Mutex mx; /**< Monitor mutex */
symposium_t* symp; /**< The symposium definition */
PHIL* state; /**< state[i] i=1...N]: Philosopher state */
CondVar* hungry; /**< hungry[i] i=...N: condition var for philosophers */
} SymposiumTable;
/** @brief Initialize a symposium monitor.
Note: this method allocates memory.
Therefore, @ref SymposiumTable_destroy must be called
@param table the monitor
@param symp the symposium
*/
void SymposiumTable_init(SymposiumTable* table, symposium_t* symp);
/** @brief Destroy a symposium monitor.
@param table the monitor
*/
void SymposiumTable_destroy(SymposiumTable* table);
/** @brief The philosopher.
This function implements philosopher logic. A symposium
consists of @c N threads or processes executing this function.
@param table the symposium monitor
@param i the philosopher index
*/
void SymposiumTable_philosopher(SymposiumTable* table, int i);
/** @brief Run a symposium using threads.
In this implememntation, each philosopher is a thread.
This program can be called as follows:
@code
symposium_t symp = ...;
Exec(SymposiumOfThreads, sizeof(symp), &symp);
@endcode
*/
int SymposiumOfThreads(int argl, void* args);
/** @brief Run a symposium using processes.
In this implememntation, each philosopher is a process.
This program can be called as follows:
@code
symposium_t symp = ...;
Exec(SymposiumProcesses, sizeof(symp), &symp);
@endcode
*/
int SymposiumOfProcesses(int argl, void* args);
#endif