我工作需要用到一个厂家的OCX控件,他有一个方法是这样的:GetStatusReasons 方法
说明:
返回 StatusReason 对象集。此集只包含与座席的当前状态相关的返回状态原因。返回一个集合
的状态是“未就绪”和“注销”状态,对于其它状态,集合不返回值。
语法:
Set StatusReasonObject = object.GetStatusReasons(State as
StateConstants)
VB 示例:
Dim objStatusReason as CCPROAgentCtl.StatusReason
For Each objStatusReason in
CCApplication1.GetStatusReasons(ccpNotReady)
lstStatusReasons.AddItem objStatusReason.Description
lstStatusReasons.ItemData(lstStatusReasons.NewIndex) =
objStatusReasons.ID
Next但我不知道如何用VC得到此方法的每一个原因,我的代码如下long lnStatus = ccpNotready;
C_StatusReason sr;
C_StatusReasons srs = m_ctlApplication.GetStatusReasons(&lnStatus);sr = srs.GetItem(VARIANT * vntIndexKey); // 此处报错, C_StatusReason和C_StatusReasons都是继承于COleDispatchDriver,求教如何给此类变量赋值
说明:
返回 StatusReason 对象集。此集只包含与座席的当前状态相关的返回状态原因。返回一个集合
的状态是“未就绪”和“注销”状态,对于其它状态,集合不返回值。
语法:
Set StatusReasonObject = object.GetStatusReasons(State as
StateConstants)
VB 示例:
Dim objStatusReason as CCPROAgentCtl.StatusReason
For Each objStatusReason in
CCApplication1.GetStatusReasons(ccpNotReady)
lstStatusReasons.AddItem objStatusReason.Description
lstStatusReasons.ItemData(lstStatusReasons.NewIndex) =
objStatusReasons.ID
Next但我不知道如何用VC得到此方法的每一个原因,我的代码如下long lnStatus = ccpNotready;
C_StatusReason sr;
C_StatusReasons srs = m_ctlApplication.GetStatusReasons(&lnStatus);sr = srs.GetItem(VARIANT * vntIndexKey); // 此处报错, C_StatusReason和C_StatusReasons都是继承于COleDispatchDriver,求教如何给此类变量赋值
Use VARIANTARG to describe arguments passed within DISPPARAMS, and VARIANT to specify variant data that cannot be passed by reference. The VARIANT type cannot have the VT_BYREF bit set. VARIANTs can be passed by value, even if VARIANTARGs cannot.typedef struct FARSTRUCT tagVARIANT VARIANT;
typedef struct FARSTRUCT tagVARIANT VARIANTARG;typedef struct tagVARIANT {
VARTYPE vt;
unsigned short wReserved1;
unsigned short wReserved2;
unsigned short wReserved3;
union {
unsigned char bVal; // VT_UI1.
short iVal; // VT_I2 .
long lVal; // VT_I4 .
float fltVal; // VT_R4 .
double dblVal; // VT_R8 .
VARIANT_BOOL boolVal; // VT_BOOL.
SCODE scode; // VT_ERROR.
CY cyVal; // VT_CY .
DATE date; // VT_DATE.
BSTR bstrVal; // VT_BSTR.
IUnknown FAR* punkVal; // VT_UNKNOWN.
IDispatch FAR* pdispVal; // VT_DISPATCH.
SAFEARRAY FAR* parray; // VT_ARRAY|*.
unsigned char FAR* pbVal; // VT_BYREF|VT_UI1.
short FAR* piVal; // VT_BYREF|VT_I2.
long FAR* plVal; // VT_BYREF|VT_I4.
float FAR* pfltVal; // VT_BYREF|VT_R4.
double FAR* pdblVal; // VT_BYREF|VT_R8.
VARIANT_BOOL FAR* pboolVal; // VT_BYREF|VT_BOOL.
SCODE FAR* pscode; // VT_BYREF|VT_ERROR.
CY FAR* pcyVal; // VT_BYREF|VT_CY.
DATE FAR* pdate; // VT_BYREF|VT_DATE.
BSTR FAR* pbstrVal; // VT_BYREF|VT_BSTR.
IUnknown FAR* FAR* ppunkVal; // VT_BYREF|VT_UNKNOWN.
IDispatch FAR* FAR* ppdispVal; // VT_BYREF|VT_DISPATCH.
SAFEARRAY FAR* FAR* pparray; // VT_ARRAY|*.
VARIANT FAR* pvarVal; // VT_BYREF|VT_VARIANT.
void FAR* byref; // Generic ByRef.
};
};
To simplify extracting values from VARIANTARGs, Automation provides a set of functions for manipulating this type. Use of these functions is strongly recommended to ensure that applications apply consistent coercion rules.The vt value governs the interpretation of the union as follows:Value Description
VT_EMPTY No value was specified. If an optional argument to an Automation method is left blank, do not pass a VARIANT of type VT_EMPTY. Instead, pass a VARIANT of type VT_ERROR with a value of DISP_E_PARAMNOTFOUND.
VT_EMPTY | VT_BYREF Not valid.
VT_UI1 An unsigned 1-byte character is stored in bVal.
VT_UI1 | VT_BYREF A reference to an unsigned 1-byte character was passed. A pointer to the value is in pbVal.
VT_I2 A 2-byte integer value is stored in iVal.
VT_I2 | VT_BYREF A reference to a 2-byte integer was passed. A pointer to the value is in piVal.
VT_I4 A 4-byte integer value is stored in lVal.
VT_I4 | VT_BYREF A reference to a 4-byte integer was passed. A pointer to the value is in plVal.
VT_R4 An IEEE 4-byte real value is stored in fltVal.
VT_R4 | VT_BYREF A reference to an IEEE 4-byte real value was passed. A pointer to the value is in pfltVal.
VT_R8 An 8-byte IEEE real value is stored in dblVal.
VT_R8 | VT_BYREF A reference to an 8-byte IEEE real value was passed. A pointer to its value is in pdblVal.
VT_CY A currency value was specified. A currency number is stored as an 8-byte, two's complement integer, scaled by 10,000 to give a fixed-point number with 15 digits to the left of the decimal point and 4 digits to the right. The value is in cyVal.
VT_CY | VT_BYREF A reference to a currency value was passed. A pointer to the value is in pcyVal.
VT_BSTR A string was passed; it is stored in bstrVal. This pointer must be obtained and freed by the BSTR functions, which are described in Chapter 7, "Conversion and Manipulation Functions."
VT_BSTR | VT_BYREF A reference to a string was passed. A BSTR* that points to a BSTR is in pbstrVal. The referenced pointer must be obtained or freed by the BSTR functions.
VT_NULL A propagating null value was specified. (This should not be confused with the null pointer.) The null value is used for tri-state logic, as with SQL.
VT_NULL | VT_BYREF Not valid.
VT_ERROR An SCODE was specified. The type of the error is specified in scodee. Generally, operations on error values should raise an exception or propagate the error to the return value, as appropriate.
VT_ERROR | VT_BYREF A reference to an SCODE was passed. A pointer to the value is in pscode.
VT_BOOL A Boolean (True/False) value was specified. A value of 0xFFFF (all bits 1) indicates True; a value of 0 (all bits 0) indicates False. No other values are valid.
VT_BOOL | VT_BYREF A reference to a Boolean value. A pointer to the Boolean value is in pbool.
VT_DATE A value denoting a date and time was specified. Dates are represented as double-precision numbers, where midnight, January 1, 1900 is 2.0, January 2, 1900 is 3.0, and so on. The value is passed in date.
This is the same numbering system used by most spreadsheet programs, although some specify incorrectly that February 29, 1900 existed, and thus set January 1, 1900 to 1.0. The date can be converted to and from an MS-DOS representation using VariantTimeToDosDateTime, which is discussed in Chapter 7, "Conversion and Manipulation Functions."
VT_DATE | VT_BYREF A reference to a date was passed. A pointer to the value is in pdate.
VT_DISPATCH A pointer to an object was specified. The pointer is in pdispVal. This object is known only to implement IDispatch. The object can be queried as to whether it supports any other desired interface by calling QueryInterface on the object. Objects that do not implement IDispatch should be passed using VT_UNKNOWN.
VT_DISPATCH | VT_BYREF A pointer to a pointer to an object was specified. The pointer to the object is stored in the location referred to by ppdispVal.
VT_VARIANT Invalid. VARIANTARGs must be passed by reference.
VT_VARIANT | VT_BYREF A pointer to another VARIANTARG is passed in pvarVal. This referenced VARIANTARG will never have the VT_BYREF bit set in vt, so only one level of indirection can ever be present. This value can be used to support languages that allow functions to change the types of variables passed by reference.
VT_UNKNOWN A pointer to an object that implements the IUnknown interface is passed in punkVal.
VT_UNKNOWN | VT_BYREF A pointer to the IUnknown interface is passed in ppunkVal. The pointer to the interface is stored in the location referred to by ppunkVal.
VT_ARRAY | <anything> An array of data type <anything> was passed. (VT_EMPTY and VT_NULL are invalid types to combine with VT_ARRAY.) The pointer in pbyrefVal points to an array descriptor, which describes the dimensions, size, and in-memory location of the array. The array descriptor is never accessed directly, but instead is read and modified using the functions described in Chapter 7, "Conversion and Manipulation Functions."