MySQL NDB 群集 8.1 手册
MySQL NDB 群集 8.0 手册
NDB 群集内部手册
在 NDB 群集源代码发行版中,storage/ndb/ndbapi-examples
目录 storage/ndb/ndbapi-examples/common
包含四个头文件,其中包含用于示例 NDB API 程序的实用程序。(错误 #70550,错误 #17592990)这些文件的名称如下所示
array_adapter.hpp
:包含用于在 C++ 风格的字符串或字节数组与 NDB 内部用于VARCHAR
、CHAR
和VARBINARY
类型的格式之间进行转换的实用程序类。error_handling.hpp
:包含错误处理函数。ndb_util.hpp
:定义了一个处理NDB
列类型的column_type_to_string()
函数。util.hpp
:提供了一种生成任意长度字符串的方法。
本节后面是每个头文件的源代码清单。
array_adapter.hpp
#ifndef ARRAY_ADAPTER_HPP
#define ARRAY_ADAPTER_HPP
#include <algorithm>
#include <assert.h>
/*
Utility classes to convert between C++ strings/byte arrays and the
internal format used for [VAR]CHAR/BINARY types.
Base class that can be used for read operations. The column type is
taken from the NdbRecAttr object, so only one object is needed to
convert from different [VAR]CHAR/BINARY types. No additional memory
is allocated.
*/
class ReadOnlyArrayAdapter {
public:
ReadOnlyArrayAdapter() {}
enum ErrorType {Success,
InvalidColumnType,
InvalidArrayType,
InvalidNullColumn,
InvalidNullAttribute,
InvalidNullaRef,
BytesOutOfRange,
UnknownError};
/*
Return a C++ string from the aRef() value of attr. This value
will use the column and column type from attr. The advantage is
for reading; the same ArrayAdapter can be used for multiple
columns. The disadvantage is; passing an attribute not of
[VAR]CHAR/BINARY type will result in a traditional exit(-1)
*/
std::string get_string(const NdbRecAttr* attr,
ErrorType& error) const;
/* Calculate the first_byte and number of bytes in aRef for attr */
void get_byte_array(const NdbRecAttr* attr,
const char*& first_byte,
size_t& bytes,
ErrorType& error) const;
/* Check if a column is of type [VAR]BINARY */
bool is_binary_array_type(const NdbDictionary::Column::Type t) const;
/* Check if a column is of type [VAR]BINARY or [VAR]CHAR */
bool is_array_type(const NdbDictionary::Column::Type t) const;
private:
/* Disable copy constructor */
ReadOnlyArrayAdapter(const ReadOnlyArrayAdapter& a) {}
};
/*
Extension to ReadOnlyArrayAdapter to be used together with
insert/write/update operations. Memory is allocated for each
call to make_aRef or allocate_in_bytes. The memory allocated will
be deallocated by the destructor. To save memory, the scope of an
instance of this class should not be longer than the life time of
the transaction. On the other hand, it must be long enough for the
usage of all references created
*/
class ReadWriteArrayAdapter : public ReadOnlyArrayAdapter {
public:
ReadWriteArrayAdapter() {}
/* Destructor, the only place where memory is deallocated */
~ReadWriteArrayAdapter();
/*
Create a binary representation of the string 's' and return a
pointer to it. This pointer can later be used as argument to for
example setValue
*/
char* make_aRef(const NdbDictionary::Column* column,
std::string s,
ErrorType& error);
/*
Allocate a number of bytes suitable for this column type. aRef
can later be used as argument to for example setValue. first_byte
is the first byte to store data to. bytes is the number of bytes
to allocate
*/
void allocate_in_bytes(const NdbDictionary::Column* column,
char*& aRef,
char*& first_byte,
size_t bytes,
ErrorType& error);
private:
/* Disable copy constructor */
ReadWriteArrayAdapter(const ReadWriteArrayAdapter& a)
:ReadOnlyArrayAdapter() {}
/* Record of allocated char arrays to delete by the destructor */
std::vector<char*> aRef_created;
};
inline ReadWriteArrayAdapter::~ReadWriteArrayAdapter()
{
for (std::vector<char*>::iterator i = aRef_created.begin();
i != aRef_created.end();
++i) {
delete [] *i;
}
}
char*
ReadWriteArrayAdapter::
make_aRef(const NdbDictionary::Column* column,
std::string input,
ErrorType& error)
{
char* new_ref;
char* data_start;
/*
Allocate bytes and push them into the aRef_created vector.
After this operation, new_ref has a complete aRef to use in insertion
and data_start has ptr from which data is to be written.
The new_aref returned is padded completely with blank spaces.
*/
allocate_in_bytes(column, new_ref, data_start, input.length(), error);
if(error != Success)
{
return NULL;
}
/*
Copy the input string into aRef's data pointer
without affecting remaining blank spaces at end.
*/
strncpy(data_start, input.c_str(), input.length());
return new_ref;
}
void
ReadWriteArrayAdapter::
allocate_in_bytes(const NdbDictionary::Column* column,
char*& aRef,
char*& first_byte,
size_t bytes,
ErrorType& error)
{
bool is_binary;
char zero_char;
NdbDictionary::Column::ArrayType array_type;
size_t max_length;
/* unless there is going to be any problem */
error = Success;
if (column == NULL)
{
error = InvalidNullColumn;
aRef = NULL;
first_byte = NULL;
return;
}
if (!is_array_type(column->getType()))
{
error = InvalidColumnType;
aRef = NULL;
first_byte = NULL;
return;
}
is_binary = is_binary_array_type(column->getType());
zero_char = (is_binary ? 0 : ' ');
array_type = column->getArrayType();
max_length = column->getLength();
if (bytes > max_length)
{
error = BytesOutOfRange;
aRef = NULL;
first_byte = NULL;
return;
}
switch (array_type) {
case NdbDictionary::Column::ArrayTypeFixed:
/* no need to store length bytes */
aRef = new char[max_length];
first_byte = aRef;
/* pad the complete string with blank space (or) null bytes */
for (size_t i=0; i < max_length; i++) {
aRef[i] = zero_char;
}
break;
case NdbDictionary::Column::ArrayTypeShortVar:
/* byte length stored over first byte. no padding required */
aRef = new char[1 + bytes];
first_byte = aRef + 1;
aRef[0] = (char)bytes;
break;
case NdbDictionary::Column::ArrayTypeMediumVar:
/* byte length stored over first two bytes. no padding required */
aRef = new char[2 + bytes];
first_byte = aRef + 2;
aRef[0] = (char)(bytes % 256);
aRef[1] = (char)(bytes / 256);
break;
}
aRef_created.push_back(aRef);
}
std::string ReadOnlyArrayAdapter::get_string(const NdbRecAttr* attr,
ErrorType& error) const
{
size_t attr_bytes= 0;
const char* data_ptr= NULL;
std::string result= "";
/* get the beginning of data and its size.. */
get_byte_array(attr, data_ptr, attr_bytes, error);
if(error != Success)
{
return result;
}
/* ..and copy the value into result */
result = string(data_ptr, attr_bytes);
/* special treatment for FixedArrayType to eliminate padding characters */
if(attr->getColumn()->getArrayType() == NdbDictionary::Column::ArrayTypeFixed)
{
char padding_char = ' ';
std::size_t last = result.find_last_not_of(padding_char);
result = result.substr(0, last+1);
}
return result;
}
void
ReadOnlyArrayAdapter::
get_byte_array(const NdbRecAttr* attr,
const char*& data_ptr,
size_t& bytes,
ErrorType& error) const
{
/* unless there is a problem */
error= Success;
if (attr == NULL)
{
error = InvalidNullAttribute;
return;
}
if (!is_array_type(attr->getType()))
{
error = InvalidColumnType;
return;
}
const NdbDictionary::Column::ArrayType array_type =
attr->getColumn()->getArrayType();
const size_t attr_bytes = attr->get_size_in_bytes();
const char* aRef = attr->aRef();
if(aRef == NULL)
{
error= InvalidNullaRef;
return;
}
switch (array_type) {
case NdbDictionary::Column::ArrayTypeFixed:
/* no length bytes stored with aRef */
data_ptr = aRef;
bytes = attr_bytes;
break;
case NdbDictionary::Column::ArrayTypeShortVar:
/* first byte of aRef has length of the data */
data_ptr = aRef + 1;
bytes = (size_t)(aRef[0]);
break;
case NdbDictionary::Column::ArrayTypeMediumVar:
/* first two bytes of aRef has length of the data */
data_ptr = aRef + 2;
bytes = (size_t)(aRef[1]) * 256 + (size_t)(aRef[0]);
break;
default:
/* should never reach here */
data_ptr = NULL;
bytes = 0;
error = InvalidArrayType;
break;
}
}
bool
ReadOnlyArrayAdapter::
is_binary_array_type(const NdbDictionary::Column::Type t) const
{
bool is_binary;
switch (t)
{
case NdbDictionary::Column::Binary:
case NdbDictionary::Column::Varbinary:
case NdbDictionary::Column::Longvarbinary:
is_binary = true;
break;
default:
is_binary = false;
}
return is_binary;
}
bool
ReadOnlyArrayAdapter::
is_array_type(const NdbDictionary::Column::Type t) const
{
bool is_array;
switch (t)
{
case NdbDictionary::Column::Binary:
case NdbDictionary::Column::Varbinary:
case NdbDictionary::Column::Longvarbinary:
case NdbDictionary::Column::Char:
case NdbDictionary::Column::Varchar:
case NdbDictionary::Column::Longvarchar:
is_array = true;
break;
default:
is_array = false;
}
return is_array;
}
#endif // #ifndef ARRAY_ADAPTER_HPP
error_handling.hpp
#ifndef ERROR_HANDLING_HPP
#define ERROR_HANDLING_HPP
template <typename T>
inline static void print_if_not_equal(T got,
T expected,
const char* msg,
const char* file,
int line)
{
std::cout << "Got value " << got << " instead of expected value " << expected
<< " in " << file << ":" << line;
}
#define PRINT_IF_NOT_EQUAL(got, expected, msg) { \
if (got != expected) { \
print_if_not_equal(got, expected, msg, __FILE__, __LINE__); \
exit(-1); \
} \
}
#define PRINT_ERROR(code,msg) \
std::cout << "Error in " << __FILE__ << ", line: " << __LINE__ \
<< ", code: " << code \
<< ", msg: " << msg << "." << std::endl
#define APIERROR(error) { \
PRINT_ERROR(error.code,error.message); \
exit(-1); }
#endif
ndb_util.hpp
#ifndef NDB_UTIL_HPP
#define NDB_UTIL_HPP
#include <NdbApi.hpp>
#include <string>
#include <sstream>
static const std::string column_type_to_string(NdbDictionary::Column::Type type)
{
switch (type)
{
case NdbDictionary::Column::Undefined:
return "Undefined";
case NdbDictionary::Column::Tinyint:
return "Tinyint";
case NdbDictionary::Column::Tinyunsigned:
return "Tinyunsigned";
case NdbDictionary::Column::Smallint:
return "Smallint";
case NdbDictionary::Column::Smallunsigned:
return "Smallunsigned";
case NdbDictionary::Column::Mediumint:
return "Mediumint";
case NdbDictionary::Column::Mediumunsigned:
return "Mediumunsigned";
case NdbDictionary::Column::Int:
return "Int";
case NdbDictionary::Column::Unsigned:
return "Unsigned";
case NdbDictionary::Column::Bigint:
return "Bigint";
case NdbDictionary::Column::Bigunsigned:
return "Bigunsigned";
case NdbDictionary::Column::Float:
return "Float";
case NdbDictionary::Column::Double:
return "Double";
case NdbDictionary::Column::Olddecimal:
return "Olddecimal";
case NdbDictionary::Column::Olddecimalunsigned:
return "Olddecimalunsigned";
case NdbDictionary::Column::Decimal:
return "Decimal";
case NdbDictionary::Column::Decimalunsigned:
return "Decimalunsigned";
case NdbDictionary::Column::Char:
return "Char";
case NdbDictionary::Column::Varchar:
return "Varchar";
case NdbDictionary::Column::Binary:
return "Binary";
case NdbDictionary::Column::Varbinary:
return "Varbinary";
case NdbDictionary::Column::Datetime:
return "Datetime";
case NdbDictionary::Column::Date:
return "Date";
case NdbDictionary::Column::Blob:
return "Blob";
case NdbDictionary::Column::Text:
return "Text";
case NdbDictionary::Column::Bit:
return "Bit";
case NdbDictionary::Column::Longvarchar:
return "Longvarchar";
case NdbDictionary::Column::Longvarbinary:
return "Longvarbinary";
case NdbDictionary::Column::Time:
return "Time";
case NdbDictionary::Column::Year:
return "Year";
case NdbDictionary::Column::Timestamp:
return "Timestamp";
case NdbDictionary::Column::Time2:
return "Time2";
case NdbDictionary::Column::Datetime2:
return "Datetime2";
case NdbDictionary::Column::Timestamp2:
return "Timestamp2";
default:
{
std::string str;
std::stringstream s(str);
s << "Unknown type: " << type;
return s.str();
}
}
}
#endif
util.hpp
#include <string>
/* Return a string containing 'n' copies of the string 's'. */
static std::string operator * (unsigned n, const std::string& s)
{
std::string result;
result.reserve(n * s.length());
for (unsigned i = 0; i < n; i++)
{
result.append(s);
}
return result;
}
#endif // #ifndef UTIL_HPP