mariadb/storage/cassandra/ha_cassandra.h

/* 
  MP AB copyrights 
*/
#ifdef USE_PRAGMA_INTERFACE
#pragma interface			/* gcc class implementation */
#endif


#include "my_global.h"                   /* ulonglong */
#include "thr_lock.h"                    /* THR_LOCK, THR_LOCK_DATA */
#include "handler.h"                     /* handler */
#include "my_base.h"                     /* ha_rows */

#include "cassandra_se.h"

/** @brief
  CASSANDRA_SHARE is a structure that will be shared among all open handlers.
  This example implements the minimum of what you will probably need.
*/
typedef struct st_cassandra_share {
  char *table_name;
  uint table_name_length,use_count;
  mysql_mutex_t mutex;
  THR_LOCK lock;
} CASSANDRA_SHARE;

class ColumnDataConverter;

/** @brief
  Class definition for the storage engine
*/
class ha_cassandra: public handler
{
  THR_LOCK_DATA lock;      ///< MySQL lock
  CASSANDRA_SHARE *share;    ///< Shared lock info
  
  Cassandra_se_interface *se;

  /* pre-allocated array of #fields elements */
  NameAndValue *names_and_vals;
  NameAndValue *get_names_and_vals();


  ColumnDataConverter **field_converters;
  uint n_field_converters;
  bool setup_field_converters(Field **field, uint n_fields);
  void free_field_converters();
public:
  ha_cassandra(handlerton *hton, TABLE_SHARE *table_arg);
  ~ha_cassandra()
  {
    delete se;
  }

  /** @brief
    The name that will be used for display purposes.
   */
  const char *table_type() const { return "CASSANDRA"; }

  /** @brief
    The name of the index type that will be used for display.
    Don't implement this method unless you really have indexes.
   */
  const char *index_type(uint inx) { return "HASH"; }

  /** @brief
    The file extensions.
   */
  const char **bas_ext() const;

  /** @brief
    This is a list of flags that indicate what functionality the storage engine
    implements. The current table flags are documented in handler.h
  */
  ulonglong table_flags() const
  {
    /*
      We are saying that this engine is just statement capable to have
      an engine that can only handle statement-based logging. This is
      used in testing.
    */
    return HA_BINLOG_STMT_CAPABLE;
  }

  /** @brief
    This is a bitmap of flags that indicates how the storage engine
    implements indexes. The current index flags are documented in
    handler.h. If you do not implement indexes, just return zero here.

      @details
    part is the key part to check. First key part is 0.
    If all_parts is set, MySQL wants to know the flags for the combined
    index, up to and including 'part'.
  */
  ulong index_flags(uint inx, uint part, bool all_parts) const
  {
    return 0;
  }

  /** @brief
    unireg.cc will call max_supported_record_length(), max_supported_keys(),
    max_supported_key_parts(), uint max_supported_key_length()
    to make sure that the storage engine can handle the data it is about to
    send. Return *real* limits of your storage engine here; MySQL will do
    min(your_limits, MySQL_limits) automatically.
   */
  uint max_supported_record_length() const { return HA_MAX_REC_LENGTH; }

  /* Support only one Primary Key, for now */
  uint max_supported_keys()          const { return 1; }
  uint max_supported_key_parts()     const { return 1; }

  /** @brief
    unireg.cc will call this to make sure that the storage engine can handle
    the data it is about to send. Return *real* limits of your storage engine
    here; MySQL will do min(your_limits, MySQL_limits) automatically.

      @details
    There is no need to implement ..._key_... methods if your engine doesn't
    support indexes.
   */
  uint max_supported_key_length()    const { return 16*1024; /* just to return something*/ }
  
  /* At the moment, we're ok with default handler::index_init() implementation. */
  int index_read_map(uchar * buf, const uchar * key,
                     key_part_map keypart_map,
                     enum ha_rkey_function find_flag);

  /** @brief
    Called in test_quick_select to determine if indexes should be used.
  */
  virtual double scan_time() { return (double) (stats.records+stats.deleted) / 20.0+10; }

  /** @brief
    This method will never be called if you do not implement indexes.
  */
  virtual double read_time(uint, uint, ha_rows rows)
  { return (double) rows /  20.0+1; }

  /*
    Everything below are methods that we implement in ha_example.cc.

    Most of these methods are not obligatory, skip them and
    MySQL will treat them as not implemented
  */
  /** @brief
    We implement this in ha_example.cc; it's a required method.
  */
  int open(const char *name, int mode, uint test_if_locked);    // required

  /** @brief
    We implement this in ha_example.cc; it's a required method.
  */
  int close(void);                                              // required

  /** @brief
    We implement this in ha_example.cc. It's not an obligatory method;
    skip it and and MySQL will treat it as not implemented.
  */
  int write_row(uchar *buf);

  /** @brief
    We implement this in ha_example.cc. It's not an obligatory method;
    skip it and and MySQL will treat it as not implemented.
  */
  int update_row(const uchar *old_data, uchar *new_data);

  /** @brief
    We implement this in ha_example.cc. It's not an obligatory method;
    skip it and and MySQL will treat it as not implemented.
  */
  int delete_row(const uchar *buf);

  /** @brief
    We implement this in ha_example.cc. It's not an obligatory method;
    skip it and and MySQL will treat it as not implemented.
  */
  int index_next(uchar *buf);

  /** @brief
    We implement this in ha_example.cc. It's not an obligatory method;
    skip it and and MySQL will treat it as not implemented.
  */
  int index_prev(uchar *buf);

  /** @brief
    We implement this in ha_example.cc. It's not an obligatory method;
    skip it and and MySQL will treat it as not implemented.
  */
  int index_first(uchar *buf);

  /** @brief
    We implement this in ha_example.cc. It's not an obligatory method;
    skip it and and MySQL will treat it as not implemented.
  */
  int index_last(uchar *buf);

  /** @brief
    Unlike index_init(), rnd_init() can be called two consecutive times
    without rnd_end() in between (it only makes sense if scan=1). In this
    case, the second call should prepare for the new table scan (e.g if
    rnd_init() allocates the cursor, the second call should position the
    cursor to the start of the table; no need to deallocate and allocate
    it again. This is a required method.
  */
  int rnd_init(bool scan);                                      //required
  int rnd_end();
  int rnd_next(uchar *buf);                                     ///< required
  int rnd_pos(uchar *buf, uchar *pos);                          ///< required
  void position(const uchar *record);                           ///< required
  int info(uint);                                               ///< required
  int extra(enum ha_extra_function operation);
  int external_lock(THD *thd, int lock_type);                   ///< required
  int delete_all_rows(void);
  ha_rows records_in_range(uint inx, key_range *min_key,
                           key_range *max_key);
  int delete_table(const char *from);
  int create(const char *name, TABLE *form,
             HA_CREATE_INFO *create_info);                      ///< required
  bool check_if_incompatible_data(HA_CREATE_INFO *info,
                                  uint table_changes);

  THR_LOCK_DATA **store_lock(THD *thd, THR_LOCK_DATA **to,
                             enum thr_lock_type lock_type);     ///< required
};