Our example program is a fairly simple transactional application. At this early stage of its development, the application contains no hint that it must be network-aware so the only command line argument that it takes is one that allows us to specify the environment home directory. (Eventually, we will specify things like host names and ports from the command line).
Note that the application performs all writes under the protection of a transaction; however, multiple database operations are not performed per transaction. Consequently, we simplify things a bit by using autocommit for our database writes.
Also, this application is single-threaded. It is possible to write a multi-threaded or multi-process application that performs replication. That said, the concepts described in this book are applicable to both single threaded and multi-threaded applications so nothing is gained by multi-threading this application other than distracting complexity. This manual does, however, identify where care must be taken when performing replication with a non-single threaded application.
Finally, remember that transaction processing is not described in this manual. Rather, see the Berkeley DB Getting Started with Transaction Processing guide for details on that topic.
Before we begin, we present a class that we will use to maintain useful information for us. Under normal circumstances, this class would not be necessary for a simple transactional example such as this. However, this code will grow into a replicated example that needs to track a lot more information for the application, and so we lay the groundwork for it here.
The class that we create is called
RepConfigInfo
and its only purpose at this time is to track
the location of our environment home directory.
#include <db_cxx.h> class RepConfigInfo { public: RepConfigInfo(); virtual ~RepConfigInfo(); public: char* home; }; RepConfigInfo::RepConfigInfo() { home = "TESTDIR"; } RepConfigInfo::~RepConfigInfo() { }
Our transactional example will
instantiate a class,
SimpleTxn
, that performs
all our work for us. Before we implement our
main()
function, we show
the SimpleTxn
class
declaration.
First, we provide some declarations and definitions that are needed later in our example:
#include <iostream> #include <db_cxx.h> #include "RepConfig.h" using std::cout; using std::cin; using std::cerr; using std::endl; using std::flush; #define CACHESIZE (10 * 1024 * 1024) #define DATABASE "quote.db" const char *progname = "excxx_reqquote_gsg_simple"; #ifdef _WIN32 #define WIN32_LEAN_AND_MEAN #include <windows.h> #include <direct.h> extern "C" { extern int getopt(int, char * const *, const char *); extern char *optarg; } #else #include <errno.h> #endif
And then we define our SimpleTxn
class:
class SimpleTxn { public: // Constructor. SimpleTxn(); // Initialization method. Creates and opens our environment handle. int init(RepConfigInfo* config); // The doloop is where all the work is performed. int doloop(); // terminate() provides our shutdown code. int terminate(); private: // disable copy constructor. SimpleTxn(const SimpleTxn &); void operator = (const SimpleTxn &); // internal data members. RepConfigInfo *app_config; DbEnv dbenv; // private methods. // print_stocks() is used to display the contents of our database. static int print_stocks(Db *dbp); };
Note that we show the implementation of the various
SimpleTxn
methods later in this section.
Our usage()
is at this
stage of development trivial because we only
have one command line argument to manage.
Still, we show it here for the sake of
completeness.
static void usage() { cerr << "usage: " << progname << endl << "-h home" << endl; exit(EXIT_FAILURE); }
Now we provide our main()
function. This is a trivial function whose only
job is to collect command line information,
then instantiate a SimpleTxn
object, run it, then terminate it.
We begin by declaring some useful variables. Of
these, note that we instantiate our
RepConfigInfo
object here. Recall that this is used to store
information useful to our code. This class becomes more
interesting later in this book.
int main(int argc, char **argv) { RepConfigInfo config; char ch; int ret;
Then we collect our command line information. Again, this is at this point fairly trivial:
// Extract the command line parameters while ((ch = getopt(argc, argv, "h:")) != EOF) { switch (ch) { case 'h': config.home = optarg; break; case '?': default: usage(); } } // Error check command line. if (config.home == NULL) usage();
Now we instantiate and initialize our SimpleTxn
class, which is what is responsible for doing all our real work.
The SimpleTxn::init()
method creates and
opens our environment handle.
SimpleTxn runner; try { if((ret = runner.init(&config)) != 0) goto err;
Then we call the SimpleTxn::doloop()
method, which is where the actual transactional work is
performed for this application.
if((ret = runner.doloop()) != 0) goto err;
Finally, catch exceptions and terminate the program:
} catch (DbException dbe) { cerr << "Caught an exception during initialization or" << " processing: " << dbe.what() << endl; } err: runner.terminate(); return 0; }
The SimpleTxn::init()
method is used to create and open our environment handle.
For readers familiar with writing transactional
DB applications, there should be no surprises
here. However, we will be adding to this in later
chapters as we roll replication into this example.
First, we show the class constructor implementation, which is only used to initialize a few variables:
SimpleTxn::SimpleTxn() : app_config(0), dbenv(0) { }
We now provide the init()
method
implementation. The only thing of interest here is that we specify
DB_TXN_NOSYNC
to our environment. This causes
our transactional commits to become non-durable, which is something
that we are doing only because of the nature of our example.
int SimpleTxn::init(RepConfigInfo *config) { int ret = 0; app_config = config; dbenv.set_errfile(stderr); dbenv.set_errpfx(progname); /* * We can now open our environment. */ dbenv.set_cachesize(0, CACHESIZE, 0); dbenv.set_flags(DB_TXN_NOSYNC, 1); try { dbenv.open(app_config->home, DB_CREATE | DB_RECOVER | DB_INIT_LOCK | DB_INIT_LOG | DB_INIT_MPOOL | DB_INIT_TXN, 0); } catch(DbException dbe) { cerr << "Caught an exception during DB environment open." << endl << "Ensure that the home directory is created prior to starting" << " the application." << endl; ret = ENOENT; goto err; } err: return ret; }
Finally, we present the SimpleTxn::terminate()
method here. All this does is close the environment handle. Again,
there should be no surprises here, but we provide the
implementation for the sake of completeness anyway.
int SimpleTxn::terminate() { try { dbenv.close(0); } catch (DbException dbe) { cerr << "error closing environment: " << dbe.what() << endl; } return 0; }
Having written our main()
function and support utility methods, we now implement
our application's
primary data processing method. This
method provides a command prompt at which the
user can enter a stock ticker value and a price for
that value. This information is then entered to the
database.
To display the database, simply enter
return
at the prompt.
To begin, we declare a database pointer,
several Dbt
variables, and
the usual assortment of variables used for buffers
and return codes. We also initialize all of this.
#define BUFSIZE 1024 int SimpleTxn::doloop() { Db *dbp; Dbt key, data; char buf[BUFSIZE], *rbuf; int ret; dbp = NULL; memset(&key, 0, sizeof(key)); memset(&data, 0, sizeof(data)); ret = 0;
Next, we begin the loop and we immediately open our database if it has not already been opened. Notice that we specify autocommit when we open the database. In this case, autocommit is important because we will only ever write to our database using it. There is no need for explicit transaction handles and commit/abort code in this application, because we are not combining multiple database operations together under a single transaction.
Autocommit is described in greater detail in the Berkeley DB Getting Started with Transaction Processing guide.
for (;;) { if (dbp == NULL) { dbp = new Db(&dbenv, 0); try { dbp->open(NULL, DATABASE, NULL, DB_BTREE, DB_CREATE | DB_AUTO_COMMIT, 0); } catch(DbException dbe) { dbenv.err(ret, "DB->open"); throw dbe; } }
Now we implement our command prompt. This is a simple and not
very robust implementation of a command prompt.
If the user enters the keywords exit
or quit
, the loop is exited and the
application ends. If the user enters nothing and instead simply
presses return
, the entire contents of the
database is displayed. We use our
print_stocks()
method to display the
database. (That implementation is shown next in this chapter.)
Notice that very little error checking is performed on the data entered at this prompt. If the user fails to enter at least one space in the value string, a simple help message is printed and the prompt is returned to the user. That is the only error checking performed here. In a real-world application, at a minimum the application would probably check to ensure that the price was in fact an integer or float value. However, in order to keep this example code as simple as possible, we refrain from implementing a thorough user interface.
cout << "QUOTESERVER" ; cout << "> " << flush; if (fgets(buf, sizeof(buf), stdin) == NULL) break; if (strtok(&buf[0], " \t\n") == NULL) { switch ((ret = print_stocks(dbp))) { case 0: continue; default: dbp->err(ret, "Error traversing data"); goto err; } } rbuf = strtok(NULL, " \t\n"); if (rbuf == NULL || rbuf[0] == '\0') { if (strncmp(buf, "exit", 4) == 0 || strncmp(buf, "quit", 4) == 0) break; dbenv.errx("Format: TICKER VALUE"); continue; }
Now we assign data to the Dbt
s that
we will use to write the new information to the database.
key.set_data(buf); key.set_size((u_int32_t)strlen(buf)); data.set_data(rbuf); data.set_size((u_int32_t)strlen(rbuf));
Having done that, we can write the new information to the
database. Remember that this application uses autocommit,
so no explicit transaction management is required. Also,
the database is not configured for duplicate records, so
the data portion of a record is overwritten if the provided
key already exists in the database. However, in this case
DB returns DB_KEYEXIST
— which
we ignore.
if ((ret = dbp->put(NULL, &key, &data, 0)) != 0) { dbp->err(ret, "DB->put"); if (ret != DB_KEYEXIST) goto err; } }
Finally, we close our database before returning from the method.
err: if (dbp != NULL) { (void)dbp->close(DB_NOSYNC); cout << "database closed" << endl; } return (ret); }
The print_stocks()
method
simply takes a database handle, opens a cursor, and uses
it to display all the information it finds in a database.
This is trivial cursor operation that should hold
no surprises for you. We simply provide it here for
the sake of completeness.
If you are unfamiliar with basic cursor operations, please see the Getting Started with Berkeley DB guide.
int SimpleTxn::print_stocks(Db *dbp) { Dbc *dbc; Dbt key, data; #define MAXKEYSIZE 10 #define MAXDATASIZE 20 char keybuf[MAXKEYSIZE + 1], databuf[MAXDATASIZE + 1]; int ret, t_ret; u_int32_t keysize, datasize; if ((ret = dbp->cursor(NULL, &dbc, 0)) != 0) { dbp->err(ret, "can't open cursor"); return (ret); } memset(&key, 0, sizeof(key)); memset(&data, 0, sizeof(data)); cout << "\tSymbol\tPrice" << endl << "\t======\t=====" << endl; for (ret = dbc->get(&key, &data, DB_FIRST); ret == 0; ret = dbc->get(&key, &data, DB_NEXT)) { keysize = key.get_size() > MAXKEYSIZE ? MAXKEYSIZE : key.get_size(); memcpy(keybuf, key.get_data(), keysize); keybuf[keysize] = '\0'; datasize = data.get_size() >= MAXDATASIZE ? MAXDATASIZE : data.get_size(); memcpy(databuf, data.get_data(), datasize); databuf[datasize] = '\0'; cout << "\t" << keybuf << "\t" << databuf << endl; } cout << endl << flush; if ((t_ret = dbc->close()) != 0 && ret == 0) { cout << "closed cursor" << endl; ret = t_ret; } switch (ret) { case 0: case DB_NOTFOUND: return (0); default: return (ret); } }