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#define FREEHDL_KERNEL_DB_H
#include <assert.h>
/* This header file includes the definitions that are required to
* setup a kernel database. This database will be used by the kernel
* to store information. Each chunk of information is associated with
* a key. The key as well as the type and name of information are not
* necessarily kown to the database at compile time. E.g., new key
* types as well as new data types can be added without recompiling or
* rebuilding the database. Here is an short example on how to add and
* use the database:
// These are macro calls so DO NOT INSERT ANY SPACE BETWEEN ".._type"
// AND "("!!!
// First, we define a key that is used to store an item in the data
// base. Here, the macro creates an item db_key_type::sig_key that
// references the corresponding key type. Note that db_key_type is a
// namespace.
define_db_key_type(sig_info_base*, sig_key);
// Next, define two data types that shall be actually stored. Here the
// macro creates a new item db_entry_type::sig_name and associates it
// with the data type string. Further, a new struct is defined and
// also prepared for storing to the database. Note that db_entry_type is
// a namespace.
define_db_entry_type(string, sig_name);
// A structure shall be stored in the database
struct driver_data {
int driver_count;
bool is_resolved;
};
define_db_entry_type(driver_data, driver_data_entry)
// Now, create an database explorer instance. The database explorer is
// used to search and manipulate the database. The explorer is
// associated with the corresponding database (here: kernel_db) at
// construction. Note that we must define the data kind we are
// interested in as a template parameter to db_explorer.
db_explorer<db_key_type::sig_key, db_entry_type::sig_name> sig_info_ext (kernel_db);
// Now we can create and reference an entry. The following code will
// associate a_siginfo_pointer with an database entry
// db_entry_type::sig_name which stores the value "test". Note that
// get will automatically create an corresponding entry if the current
// a_siginfo_pointer value is not associated with this entry kind.
sig_info_ext.get (a_siginfo_pointer) = "test";
// Another explorer is created that can be used to access
// driver_data_entry. Note that an separate explorer instance must be
// used for each data entry type!
db_explorer<db_key_type::sig_key, db_entry_type::driver_data_entry>
sig_info_driver_ext (kernel_db);
sig_info_driver_ext.get (a_siginfo_pointer).is_resolved = true;
sig_info_driver_ext.get (a_siginfo_pointer).driver_count = 0;
// For other ways to access/query the databse see the db_explorer
// class.
*/
/******************************************************
* Some definitions which are used by the kernel only
******************************************************/
#ifdef KERNEL
#include <vector>
#include <freehdl/kernel-util.hh>
#if !defined __GNUC__ || __GNUC__ != 2
#include <ext/hash_map>
#else
#include <hash_map>
#endif
// Macro used to define a key type. K is the actual type of the key
// while N is his name that will be used within the kernel
// database. Note that N is created in namespace db_key_type. Hence,
// to reference it use db_key_type::N.
#define define_db_key_type(K,N) \
namespace db_key_type \
{ \
struct __kernel_db_key_type__ ## N { typedef K key_type; \
static string get_name () { return # N; } }; \
typedef db_key_kind<__kernel_db_key_type__ ## N> N; \
}
// Macro used to define a database entry type. K is the type (as
// defined by define_db_key_type, while T is the type of the data
// entry and N is his name that will be used to identify the data
// entry type. Note that N is created in namespace
// db_entry_type. Hence, to reference it use db_entry_type::N.
#define define_db_entry_type(T,N) \
namespace db_entry_type \
{ \
struct __kernel_db_entry_type__ ## N { typedef T data_type; \
static string get_name () { return # N; } }; \
typedef db_entry_kind<T, __kernel_db_entry_type__ ## N> N; \
} \
// Base class to derive all key kind classes from
class db_key_kind_base
{
public:
virtual ~db_key_kind_base() {};
virtual string get_name () = 0;
};
// The actual key kind class. This class represents the correponding
// key type. Key is the key type. This class is a singleton.
template<class Key>
class db_key_kind : public db_key_kind_base
{
private:
static db_key_kind *single_instance;
public:
static db_key_kind *get_instance ()
{
if (single_instance == NULL)
single_instance = new db_key_kind;
return single_instance;
}
protected:
db_key_kind () { };
public:
// Get name of key.
string get_name () { return Key::get_name (); }
typedef db_key_kind_base kind_base_type;
typedef typename Key::key_type key_type;
};
template<class Key>
db_key_kind<Key> *db_key_kind<Key>::single_instance = NULL;
// From the following class all entry kind classes are derived.
class db_entry_kind_base
{
public:
virtual ~db_entry_kind_base() {};
virtual string get_name () = 0;
};
// The actual entry kind class. This class represents the correponding
// database entry kind. This class is a singleton. T is the type of
// the data entry. N is the name of this data kind.
template<class T, class N>
class db_entry_kind : public db_entry_kind_base
{
private:
static db_entry_kind *single_instance;
public:
static db_entry_kind *get_instance ()
{
if (single_instance == NULL)
single_instance = new db_entry_kind;
return single_instance;
}
protected:
db_entry_kind () { };
public:
// Get name of database entry.
string get_name () { return N::get_name (); }
typedef T data_type;
typedef db_entry_kind_base kind_base_type;
};
template<class T,class N>
db_entry_kind<T,N> *db_entry_kind<T,N>::single_instance = NULL;
// Base class for all db_entry classes. THe class stores a pointer to
// the corresponding db_entry_kind.
class db_entry_base
{
public:
virtual ~db_entry_base() {};
const db_entry_kind_base *kind;
virtual string get_name () = 0;
db_entry_base (db_entry_kind_base *k) : kind (k) { };
};
// This is the class that is used to store the database data. kind is
// the db_entry_kind associated with this entry.
template<class entry_kind>
class db_entry : public db_entry_base
{
public:
typename entry_kind::data_type data;
string get_name () { return entry_kind::get_instance () -> get_name (); }
db_entry () : db_entry_base (entry_kind::get_instance ()) { };
};
class db_basic_key
{
public:
void *value;
bool operator == (const db_basic_key &k) const { return value == k.value; }
db_basic_key (void *v) { value = v; }
};
// The database base class. Defines a set of common interfaces that
// must be implemented by all databases.
class db_base
{
public:
virtual ~db_base() {};
typedef pair<db_key_kind_base*, vector<db_entry_base*> > db_key_entry_pair;
// Checks whether there is a entry in the database assoicated with
// key.
virtual bool is_in_database (db_basic_key key) = 0;
// Looks up en entry in the database. Note that this method must not
// be used if there is no entry associated with key.
virtual db_key_entry_pair &find (db_basic_key key) = 0;
// Same as find however, a new entry is created if key is not
// present in database.
virtual db_key_entry_pair &find_create (db_basic_key key, db_key_kind_base *key_kind) = 0;
// Creates a new entry with key key and associates entry data dbe
// with it.
virtual db_entry_base *add_entry (db_basic_key key, db_key_kind_base *key_kind, db_entry_base *dbe) = 0;
// Erase entry vom the database. The entry is defined by key and the
// data entry index i. Note that there may be several entries
// associated with key.
virtual bool erase (db_basic_key key, int i) = 0;
// Return number of keys stored in database.
virtual int key_count () const = 0;
};
// A hash function template used tp generate a hash number from
// d
class db_basic_key_hash : public hash<unsigned long> {
public:
size_t operator()(const db_basic_key& x) const {
return (*(hash<unsigned long> *)this)(((unsigned long)x.value)>>2);
}
};
// The acutal database definiton
class db : public db_base
{
// This mappes is the actual database.
typedef hash_map<void*, db_key_entry_pair, db_basic_key_hash> db_data_map_type;
db_data_map_type data_map;
// The transaction id is incremented each time a new key is added or
// a key is removed.
long long int transaction_id;
public:
db () : transaction_id (0) {};
// Some methods used to walk through the keys stored in the database.
class key_iterator
{
db_data_map_type::iterator iter;
public:
key_iterator () { }
key_iterator (const db_data_map_type::iterator i) { iter = i; }
key_iterator &operator ++ () { iter++; return *this; }
key_iterator operator ++ (int)
{
key_iterator tmp = *this;
iter++;
return tmp;
}
bool operator == (const key_iterator i) const { return iter == i.iter; }
bool operator != (const key_iterator i) const { return iter != i.iter; }
db_basic_key operator * () const { return db_basic_key (iter->first); }
};
key_iterator begin () { return key_iterator (data_map.begin ()); }
key_iterator end () { return key_iterator (data_map.end ()); }
// Return number of keys stored in database.
int key_count () const { return data_map.size (); }
// Checks whether there is a entry in the database assoicated with
// key.
bool is_in_database (db_basic_key key)
{
return data_map.find (key.value) != data_map.end ();
}
// Looks up en entry in the database. Note that this method must not
// be used if there is no entry associated with key.
db_key_entry_pair &find (db_basic_key key)
{
db_data_map_type::iterator iter = data_map.find (key.value);
assert (iter != data_map.end ());
return iter->second;
}
// Same as find however, a new entry is created if key is not
// present in database.
db_key_entry_pair &find_create (db_basic_key key, db_key_kind_base *key_kind)
{
if (! is_in_database (key))
{
data_map [key.value] = db_key_entry_pair (key_kind, vector<db_entry_base*> ());
// Increment transaction id to mark that a key has been
// added or removed.
transaction_id ++;
}
db_data_map_type::iterator iter = data_map.find (key.value);
return iter->second;
}
// Creates a new entry key and associates entry data dbe with it.
db_entry_base *add_entry (db_basic_key key, db_key_kind_base *key_kind, db_entry_base *dbe)
{
vector<db_entry_base*> &vec = find_create (key, key_kind).second;
vec.push_back (dbe);
return vec.back ();
}
// Erase entry vom the database. The entry is defined by key and the
// data entry index i. Note that there may be several entries
// associated with key. If there is no entry left, then the
// corresponding key is also removed from the database.
bool erase (db_basic_key key, int i)
{
db_data_map_type::iterator iter = data_map.find (key.value);
if (iter == data_map.end ()) return false;
vector<db_entry_base*> &vec = iter->second.second;
if (vec [i] != NULL)
delete vec [i];
vec.erase (vec.begin () + i);
if (vec.size () == 0)
{
data_map.erase (iter);
// Increment transaction id to mark that a key has been
// added or removed.
transaction_id ++;
}
return true;
}
};
// Operator class used to control the search operation of the database.
template<class K>
class exact_match {
public:
bool operator () (const typename K::kind_base_type *a, const typename K::kind_base_type *b)
{
return a == b;
}
};
// Operator class used to control the search operation of the database.
template<class K>
class match_all {
public:
bool operator () (const typename K::kind_base_type *a, const typename K::kind_base_type *b)
{
return true;
}
};
// Template used to cast a key to void*. Note that the actual core
// database uses void* as keys.
template<class K>
class default_key_mapper
{
public:
db_basic_key convert_to_basic_key (const typename K::key_type key) const { return db_basic_key ((void*)key); }
typename K::key_type convert_to_key (db_basic_key p) const { return (typename K::key_type)p.value; }
};
// The database explorer is used to search and manipulate the
// database. The explorer is associated with the corresponding
// database (here: kernel_db) at construction. Note that we must
// define the data kind we are interested in as a template parameter
// to the explorer.
template<class key_kind,
class kind,
class key_mapper = default_key_mapper<key_kind>,
class KM = exact_match<key_kind>,
class DM = exact_match<kind> >
class db_explorer
{
db &database;
// last_index is used to cache the last referenced entry accessed
// with this database explorer.
int last_index;
// Looks up an entry specified by key in the database. Returns NULL
// if no such entry is present (either key in not in the database or
// there is no such entry kind associated with key.
db_entry<kind> *find_entry (const typename key_kind::key_type key)
{
key_mapper keym;
if (! database.is_in_database (keym.convert_to_basic_key (key))) return NULL;
db_base::db_key_entry_pair &hit = database.find (keym.convert_to_basic_key (key));
assert (hit.second.size () > 0);
// Test whether key is assoicates with the correct key type
KM km;
if (!km (key_kind::get_instance (), hit.first)) return NULL;
// Try to check out the last match that was found by the
// explorer. This implements a simple type of cache mechanism to
// speedup lookup operations.
DM m;
if ((unsigned)last_index < hit.second.size () &&
m (kind::get_instance (), hit.second [last_index]->kind ))
{
db_entry<kind> *entry = dynamic_cast<db_entry<kind>*> (hit.second [last_index]);
assert (entry != NULL);
return entry;
}
for (unsigned int i = 0; i < hit.second.size (); i++)
if (m (kind::get_instance (), hit.second [i]->kind ))
{
db_entry<kind> *entry = dynamic_cast<db_entry<kind>*> (hit.second [i]);
assert (entry != NULL);
last_index = i;
return entry;
}
return NULL;
}
public:
db_explorer (db &d) : database (d), last_index (0) { };
// Looks up an entry specified by key in the database. Returns
// pointer to the actual database value. Returns NULL if no such
// entry is present (either key in not in the database or there is
// no such entry kind associated with key.
typename kind::data_type *find (const typename key_kind::key_type key)
{
db_entry<kind> *entry = find_entry (key);
return entry != NULL? &entry->data : NULL;
}
// Looks up an entry specified by key in the database. Returns
// pointer to the actual database value. Returns NULL if no such
// entry is present (either key in not in the database or there is
// no such entry kind associated with key.
typename kind::data_type *find (const db_basic_key key)
{
key_mapper keym;
db_entry<kind> *entry = find_entry (keym.convert_to_key (key));
return entry != NULL? &entry->data : NULL;
}
// Checks whether a key is valid, i.e., actually is a key with the
// correct type.
bool is_valid (const db_basic_key key)
{
key_mapper keym;
db_entry<kind> *entry = find_entry (keym.convert_to_key (key));
return entry != NULL;
}
// Converts basic key to the appropriate key type. Note that no
// error checking is done. I.e., the caller must esure that key
// actually refers to the correct pointer type.
typename key_kind::key_type get_key (db_basic_key key) const
{
key_mapper keym;
return keym.convert_to_key (key);
}
// Same as find but creates an new entry if there is no such entry
// present.
typename kind::data_type *find_create (const typename key_kind::key_type key)
{
db_entry<kind> *entry = find_entry (key);
if (entry == NULL)
{
key_mapper keym;
database.find_create (keym.convert_to_basic_key (key), key_kind::get_instance ());
entry = dynamic_cast<db_entry<kind>*> (database.add_entry (keym.convert_to_basic_key (key),
key_kind::get_instance (),
new db_entry<kind> ()));
}
return &entry->data;
}
typename kind::data_type *find_create (db_basic_key key) { return find_create (get_key (key)); }
// Returns pointer to the corresponding data value.
typename kind::data_type &get (const typename key_kind::key_type key)
{
return *find_create (key);
}
typename kind::data_type &get (db_basic_key key) { return get (get_key (key)); }
// Removes all entries of of kind "kind" that are associated with
// key.
bool erase (const typename key_kind::key_type key)
{
key_mapper keym;
if (! database.is_in_database (keym.convert_to_basic_key (key))) return false;
DM m;
db_base::db_key_entry_pair &hit = database.find (keym.convert_to_basic_key (key));
for (int i = 0; i < hit.second.size (); i++)
if (m (kind::get_instance (), hit.second [i]->kind))
return database.erase (keym.convert_to_basic_key (key), i);
return false;
}
bool erase (db_basic_key key) { return erase (get_key (key)); }
};
// Define a common database key
define_db_key_type(void*, generic_key);
// db_generic_explorer is a special database explorer which does not
// take the key type into account during its operations. I.e., it does
// notcheck whether the key type of a specific entry is consistent
// with the kind parameter of the template. Hence, this explorer is
// NOT ALLOWED to insert any new keys into the database.
template<class kind,
class key_mapper = default_key_mapper<db_key_type::generic_key>,
class DM = exact_match<kind> >
class db_generic_explorer
{
db_explorer <db_key_type::generic_key, kind, key_mapper, match_all<db_key_type::generic_key>, DM > internal_explorer;
public:
db_generic_explorer (db &d) : internal_explorer (d) { };
// Looks up an entry specified by key in the database. Returns
// pointer to the actual database value. Returns NULL if no such
// entry is present (either key in not in the database or there is
// no such entry kind associated with key.
typename kind::data_type *find (const typename db_key_type::generic_key::key_type key)
{
return internal_explorer.find (key);
}
// Looks up an entry specified by key in the database. Returns
// pointer to the actual database value. Returns NULL if no such
// entry is present (either key in not in the database or there is
// no such entry kind associated with key.
typename kind::data_type *find (const db_basic_key key)
{
return internal_explorer.find (key);
}
// Returns pointer to the corresponding data value.
typename kind::data_type &get (const typename db_key_type::generic_key::key_type key)
{
typename kind::data_type *d = internal_explorer.find (key);
assert (d != NULL);
return *d;
}
typename kind::data_type &get (db_basic_key key) { return get (this->get_key (key)); }
};
// The actual kernel database is a singleton pattern.
class kernel_db_singleton : public db
{
private:
static kernel_db_singleton *single_instance;
public:
static kernel_db_singleton *get_instance ()
{
if (single_instance == NULL)
single_instance = new kernel_db_singleton;
return single_instance;
}
protected:
kernel_db_singleton () { };
public:
};
// kernel_db is used to access the kernel database instance.
#define kernel_db (*kernel_db_singleton::get_instance ())
#endif /* ifdef KERNEL */
#endif
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