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Per chiamare le funzioni esportate da una libreria non gestita, un'applicazione .NET Framework richiede un prototipo di funzione nel codice gestito che rappresenta la funzione non gestita. Per creare un prototipo che consente a platform invoke di effettuare correttamente il marshalling dei dati, è necessario eseguire le operazioni seguenti:
Applicare l'attributo DllImportAttribute alla funzione o al metodo statico nel codice gestito.
Sostituire i tipi di dati gestiti per i tipi di dati non gestiti.
È possibile usare la documentazione fornita con una funzione non gestita per costruire un prototipo gestito equivalente applicando l'attributo con i relativi campi facoltativi e sostituendo i tipi di dati gestiti per i tipi non gestiti. Per istruzioni su come applicare il DllImportAttribute, consultare Utilizzo di funzioni DLL non gestite.
In questa sezione vengono forniti esempi che illustrano come creare prototipi di funzioni gestite per passare argomenti a e ricevere valori restituiti da funzioni esportate da librerie non gestite. Gli esempi illustrano anche quando usare l'attributo MarshalAsAttribute e la Marshal classe per effettuare il marshalling esplicito dei dati.
Tipi di dati di invocazione piattaforma
Nella tabella seguente sono elencati i tipi di dati usati nelle API di Windows e nelle funzioni in stile C. Molte librerie non gestite contengono funzioni che passano questi tipi di dati come parametri e valori restituiti. La terza colonna elenca il tipo di valore predefinito o la classe predefinita di .NET Framework corrispondente usata nel codice gestito. In alcuni casi, è possibile sostituire un tipo della stessa dimensione per il tipo elencato nella tabella.
| Tipo non gestito nelle API di Windows | Tipo di linguaggio C non gestito | Tipo gestito | Descrizione |
|---|---|---|---|
VOID |
void |
System.Void | Applicato a una funzione che non restituisce un valore. |
HANDLE |
void * |
System.IntPtr o System.UIntPtr | 32 bit sui sistemi operativi Windows a 32 bit, 64 bit sui sistemi operativi Windows a 64 bit. |
BYTE |
unsigned char |
System.Byte | 8 bit |
SHORT |
short |
System.Int16 | 16 bit |
WORD |
unsigned short |
System.UInt16 | 16 bit |
INT |
int |
System.Int32 | 32 bit |
UINT |
unsigned int |
System.UInt32 | 32 bit |
LONG |
long |
System.Int32 | 32 bit |
BOOL |
long |
System.Boolean o System.Int32 | 32 bit |
DWORD |
unsigned long |
System.UInt32 | 32 bit |
ULONG |
unsigned long |
System.UInt32 | 32 bit |
CHAR |
char |
System.Char | Utilizzare ANSI per decorare. |
WCHAR |
wchar_t |
System.Char | Decorare con Unicode. |
LPSTR |
char * |
System.String o System.Text.StringBuilder | Utilizzare ANSI per decorare. |
LPCSTR |
const char * |
System.String o System.Text.StringBuilder | Utilizzare ANSI per decorare. |
LPWSTR |
wchar_t * |
System.String o System.Text.StringBuilder | Decorare con Unicode. |
LPCWSTR |
const wchar_t * |
System.String o System.Text.StringBuilder | Decorare con Unicode. |
FLOAT |
float |
System.Single | 32 bit |
DOUBLE |
double |
System.Double | 64 bit |
Per i tipi corrispondenti in Visual Basic, C# e C++, vedere Introduzione alla libreria di classi .NET Framework.
PinvokeLib.dll
Il codice seguente definisce le funzioni di libreria fornite da PInvokeLib.dll. Molti esempi descritti in questa sezione chiamano questa libreria.
Esempio
// PInvokeLib.cpp : Defines the entry point for the DLL application.
//
#define PINVOKELIB_EXPORTS
#include "PInvokeLib.h"
#include <strsafe.h>
#include <objbase.h>
#include <stdio.h>
#pragma comment(lib,"ole32.lib")
BOOL APIENTRY DllMain( HANDLE hModule,
DWORD ul_reason_for_call,
LPVOID lpReserved )
{
switch (ul_reason_for_call)
{
case DLL_PROCESS_ATTACH:
case DLL_THREAD_ATTACH:
case DLL_THREAD_DETACH:
case DLL_PROCESS_DETACH:
break;
}
return TRUE;
}
//******************************************************************
// This is the constructor of a class that has been exported.
CTestClass::CTestClass()
{
m_member = 1;
}
int CTestClass::DoSomething( int i )
{
return i*i + m_member;
}
PINVOKELIB_API CTestClass* CreateTestClass()
{
return new CTestClass();
}
PINVOKELIB_API void DeleteTestClass( CTestClass* instance )
{
delete instance;
}
//******************************************************************
PINVOKELIB_API int TestArrayOfInts( int* pArray, int size )
{
int result = 0;
for ( int i = 0; i < size; i++ )
{
result += pArray[ i ];
pArray[i] += 100;
}
return result;
}
//******************************************************************
PINVOKELIB_API int TestRefArrayOfInts( int** ppArray, int* pSize )
{
int result = 0;
// CoTaskMemAlloc must be used instead of the new operator
// because code on the managed side will call Marshal.FreeCoTaskMem
// to free this memory.
int* newArray = (int*)CoTaskMemAlloc( sizeof(int) * 5 );
for ( int i = 0; i < *pSize; i++ )
{
result += (*ppArray)[i];
}
for ( int j = 0; j < 5; j++ )
{
newArray[j] = (*ppArray)[j] + 100;
}
CoTaskMemFree( *ppArray );
*ppArray = newArray;
*pSize = 5;
return result;
}
//******************************************************************
PINVOKELIB_API int TestMatrixOfInts( int pMatrix[][COL_DIM], int row )
{
int result = 0;
for ( int i = 0; i < row; i++ )
{
for ( int j = 0; j < COL_DIM; j++ )
{
result += pMatrix[i][j];
pMatrix[i][j] += 100;
}
}
return result;
}
//******************************************************************
PINVOKELIB_API int TestArrayOfStrings( char* ppStrArray[], int count )
{
int result = 0;
STRSAFE_LPSTR temp;
size_t len;
const size_t alloc_size = sizeof(char) * 10;
for ( int i = 0; i < count; i++ )
{
len = 0;
StringCchLengthA( ppStrArray[i], STRSAFE_MAX_CCH, &len );
result += len;
temp = (STRSAFE_LPSTR)CoTaskMemAlloc( alloc_size );
StringCchCopyA( temp, alloc_size, (STRSAFE_LPCSTR)"123456789" );
// CoTaskMemFree must be used instead of delete to free memory.
CoTaskMemFree( ppStrArray[i] );
ppStrArray[i] = (char *) temp;
}
return result;
}
//******************************************************************
PINVOKELIB_API int TestArrayOfStructs( MYPOINT* pPointArray, int size )
{
int result = 0;
MYPOINT* pCur = pPointArray;
for ( int i = 0; i < size; i++ )
{
result += pCur->x + pCur->y;
pCur->y = 0;
pCur++;
}
return result;
}
//******************************************************************
PINVOKELIB_API int TestStructInStruct( MYPERSON2* pPerson2 )
{
size_t len = 0;
StringCchLengthA( pPerson2->person->last, STRSAFE_MAX_CCH, &len );
len = sizeof(char) * ( len + 2 ) + 1;
STRSAFE_LPSTR temp = (STRSAFE_LPSTR)CoTaskMemAlloc( len );
StringCchCopyA( temp, len, (STRSAFE_LPSTR)"Mc" );
StringCbCatA( temp, len, (STRSAFE_LPSTR)pPerson2->person->last );
CoTaskMemFree( pPerson2->person->last );
pPerson2->person->last = (char *)temp;
return pPerson2->age;
}
//******************************************************************
PINVOKELIB_API int TestArrayOfStructs2( MYPERSON* pPersonArray, int size )
{
int result = 0;
MYPERSON* pCur = pPersonArray;
STRSAFE_LPSTR temp;
size_t len;
for ( int i = 0; i < size; i++ )
{
len = 0;
StringCchLengthA( pCur->first, STRSAFE_MAX_CCH, &len );
len++;
result += len;
len = 0;
StringCchLengthA( pCur->last, STRSAFE_MAX_CCH, &len );
len++;
result += len;
len = sizeof(char) * ( len + 2 );
temp = (STRSAFE_LPSTR)CoTaskMemAlloc( len );
StringCchCopyA( temp, len, (STRSAFE_LPCSTR)"Mc" );
StringCbCatA( temp, len, (STRSAFE_LPCSTR)pCur->last );
result += 2;
// CoTaskMemFree must be used instead of delete to free memory.
CoTaskMemFree( pCur->last );
pCur->last = (char *)temp;
pCur++;
}
return result;
}
//******************************************************************
PINVOKELIB_API void TestStructInStruct3( MYPERSON3 person3 )
{
printf( "\n\nperson passed by value:\n" );
printf( "first = %s last = %s age = %i\n\n",
person3.person.first,
person3.person.last,
person3.age );
}
//*********************************************************************
PINVOKELIB_API void TestUnion( MYUNION u, int type )
{
if ( ( type != 1 ) && ( type != 2 ) )
{
return;
}
if ( type == 1 )
{
printf( "\n\ninteger passed: %i", u.i );
}
else if ( type == 2 )
{
printf( "\n\ndouble passed: %f", u.d );
}
}
//******************************************************************
PINVOKELIB_API void TestUnion2( MYUNION2 u, int type )
{
if ( ( type != 1 ) && ( type != 2 ) )
{
return;
}
if ( type == 1 )
{
printf( "\n\ninteger passed: %i", u.i );
}
else if ( type == 2 )
{
printf( "\n\nstring passed: %s", u.str );
}
}
//******************************************************************
PINVOKELIB_API void TestCallBack( FPTR pf, int value )
{
printf( "\nReceived value: %i", value );
printf( "\nPassing to callback..." );
bool res = (*pf)(value);
if ( res )
{
printf( "Callback returned true.\n" );
}
else
{
printf( "Callback returned false.\n" );
}
}
//******************************************************************
PINVOKELIB_API void TestCallBack2( FPTR2 pf2, char* value )
{
printf( "\nReceived value: %s", value );
printf( "\nPassing to callback..." );
bool res = (*pf2)(value);
if ( res )
{
printf( "Callback2 returned true.\n" );
}
else
{
printf( "Callback2 returned false.\n" );
}
}
//******************************************************************
PINVOKELIB_API void TestStringInStruct( MYSTRSTRUCT* pStruct )
{
wprintf( L"\nUnicode buffer content: %s\n", pStruct->buffer );
// Assuming that the buffer is big enough.
StringCbCatW( pStruct->buffer, pStruct->size, (STRSAFE_LPWSTR)L"++" );
}
//******************************************************************
PINVOKELIB_API void TestStringInStructAnsi( MYSTRSTRUCT2* pStruct )
{
printf( "\nAnsi buffer content: %s\n", pStruct->buffer );
// Assuming that the buffer is big enough.
StringCbCatA( (STRSAFE_LPSTR) pStruct->buffer, pStruct->size, (STRSAFE_LPSTR)"++" );
}
//******************************************************************
PINVOKELIB_API void TestOutArrayOfStructs( int* pSize, MYSTRSTRUCT2** ppStruct )
{
const int cArraySize = 5;
*pSize = 0;
*ppStruct = (MYSTRSTRUCT2*)CoTaskMemAlloc( cArraySize * sizeof( MYSTRSTRUCT2 ));
if ( ppStruct != NULL )
{
MYSTRSTRUCT2* pCurStruct = *ppStruct;
LPSTR buffer;
*pSize = cArraySize;
STRSAFE_LPCSTR teststr = "***";
size_t len = 0;
StringCchLengthA(teststr, STRSAFE_MAX_CCH, &len);
len++;
for ( int i = 0; i < cArraySize; i++, pCurStruct++ )
{
pCurStruct->size = len;
buffer = (LPSTR)CoTaskMemAlloc( len );
StringCchCopyA( buffer, len, teststr );
pCurStruct->buffer = (char *)buffer;
}
}
}
//************************************************************************
PINVOKELIB_API char * TestStringAsResult()
{
const size_t alloc_size = 64;
STRSAFE_LPSTR result = (STRSAFE_LPSTR)CoTaskMemAlloc( alloc_size );
STRSAFE_LPCSTR teststr = "This is return value";
StringCchCopyA( result, alloc_size, teststr );
return (char *) result;
}
//************************************************************************
PINVOKELIB_API void SetData( DataType typ, void* object )
{
switch ( typ )
{
case DT_I2: printf( "Short %i\n", *((short*)object) ); break;
case DT_I4: printf( "Long %i\n", *((long*)object) ); break;
case DT_R4: printf( "Float %f\n", *((float*)object) ); break;
case DT_R8: printf( "Double %f\n", *((double*)object) ); break;
case DT_STR: printf( "String %s\n", (char*)object ); break;
default: printf( "Unknown type" ); break;
}
}
//************************************************************************
PINVOKELIB_API void TestArrayInStruct( MYARRAYSTRUCT* pStruct )
{
pStruct->flag = true;
pStruct->vals[0] += 100;
pStruct->vals[1] += 100;
pStruct->vals[2] += 100;
}
// PInvokeLib.h : The header file for the DLL application.
//
#pragma once
#define WIN32_LEAN_AND_MEAN
#include <windows.h>
// The following ifdef block is the standard way of creating macros which make exporting
// from a DLL simpler. All files within this DLL are compiled with the PINVOKELIB_EXPORTS
// symbol defined on the command line. this symbol should not be defined on any project
// that uses this DLL. This way any other project whose source files include this file see
// PINVOKELIB_API functions as being imported from a DLL, wheras this DLL sees symbols
// defined with this macro as being exported.
#ifdef PINVOKELIB_EXPORTS
#define PINVOKELIB_API __declspec(dllexport)
#else
#define PINVOKELIB_API __declspec(dllimport)
#endif
// Define the test structures
typedef struct _MYPOINT
{
int x;
int y;
} MYPOINT;
typedef struct _MYPERSON
{
char* first;
char* last;
} MYPERSON;
typedef struct _MYPERSON2
{
MYPERSON* person;
int age;
} MYPERSON2;
typedef struct _MYPERSON3
{
MYPERSON person;
int age;
} MYPERSON3;
union MYUNION
{
int i;
double d;
};
union MYUNION2
{
int i;
char str[128];
};
typedef struct _MYSTRSTRUCT
{
wchar_t* buffer;
UINT size;
} MYSTRSTRUCT;
typedef struct _MYSTRSTRUCT2
{
char* buffer;
UINT size;
} MYSTRSTRUCT2;
typedef struct _MYARRAYSTRUCT
{
bool flag;
int vals[3];
} MYARRAYSTRUCT;
// constants and pointer definitions
const int COL_DIM = 5;
typedef bool (CALLBACK *FPTR)( int i );
typedef bool (CALLBACK *FPTR2)( char* str );
// Data type codes
enum DataType
{
DT_I2 = 1,
DT_I4,
DT_R4,
DT_R8,
DT_STR
};
// This is an exported class.
class PINVOKELIB_API CTestClass
{
public:
CTestClass( void );
int DoSomething( int i );
private:
int m_member;
};
// Exports for PInvokeLib.dll
#ifdef __cplusplus
extern "C"
{
#endif
PINVOKELIB_API CTestClass* CreateTestClass();
PINVOKELIB_API void DeleteTestClass( CTestClass* instance );
PINVOKELIB_API int TestArrayOfInts( int* pArray, int size );
PINVOKELIB_API int TestRefArrayOfInts( int** ppArray, int* pSize );
PINVOKELIB_API int TestMatrixOfInts( int pMatrix[][COL_DIM], int row );
PINVOKELIB_API int TestArrayOfStrings( char* ppStrArray[], int size );
PINVOKELIB_API int TestArrayOfStructs( MYPOINT* pPointArray, int size );
PINVOKELIB_API int TestArrayOfStructs2( MYPERSON* pPersonArray, int size );
PINVOKELIB_API int TestStructInStruct( MYPERSON2* pPerson2 );
PINVOKELIB_API void TestStructInStruct3( MYPERSON3 person3 );
PINVOKELIB_API void TestUnion( MYUNION u, int type );
PINVOKELIB_API void TestUnion2( MYUNION2 u, int type );
PINVOKELIB_API void TestCallBack( FPTR pf, int value );
PINVOKELIB_API void TestCallBack2( FPTR2 pf2, char* value );
// buffer is an in/out param
PINVOKELIB_API void TestStringInStruct( MYSTRSTRUCT* pStruct );
// buffer is in/out param
PINVOKELIB_API void TestStringInStructAnsi( MYSTRSTRUCT2* pStruct );
PINVOKELIB_API void TestOutArrayOfStructs( int* pSize, MYSTRSTRUCT2** ppStruct );
PINVOKELIB_API char* TestStringAsResult();
PINVOKELIB_API void SetData( DataType typ, void* object );
PINVOKELIB_API void TestArrayInStruct( MYARRAYSTRUCT* pStruct );
#ifdef __cplusplus
}
#endif
Per chiamare le funzioni di libreria dal codice gestito, implementare prototipi gestiti per ogni funzione che si vuole richiamare. Se il codice non gestito usa tipi personalizzati, è necessario dichiarare anche tali tipi nel codice gestito. Decorare ogni prototipo con l'attributo DllImportAttribute e usare StructLayoutAttribute per controllare il layout delle strutture gestite in modo che corrispondano agli equivalenti non gestiti.
Definizioni di tipi gestiti
Il codice seguente mostra gli equivalenti gestiti dei tipi non gestiti definiti in PInvokeLib.h. Ogni struttura usa StructLayout per garantire che il layout del campo corrisponda al layout non gestito:
// Managed type declarations that correspond to the unmanaged types in PinvokeLib.dll.
[StructLayout(LayoutKind.Sequential)]
internal struct MyPoint
{
public int x;
public int y;
}
[StructLayout(LayoutKind.Sequential, CharSet = CharSet.Ansi)]
internal struct MyPerson
{
public string first;
public string last;
}
[StructLayout(LayoutKind.Sequential)]
internal struct MyPerson2
{
public IntPtr person; // Pointer to a MyPerson structure
public int age;
}
[StructLayout(LayoutKind.Sequential)]
internal struct MyPerson3
{
public MyPerson person; // Embedded MyPerson structure
public int age;
}
[StructLayout(LayoutKind.Explicit)]
internal struct MyUnion
{
[FieldOffset(0)] public int i;
[FieldOffset(0)] public double d;
}
[StructLayout(LayoutKind.Sequential)]
internal struct MyArrayStruct
{
public bool flag;
[MarshalAs(UnmanagedType.ByValArray, SizeConst = 3)]
public int[] vals;
}
' Managed type declarations that correspond to the unmanaged types in PinvokeLib.dll.
<StructLayout(LayoutKind.Sequential)>
Friend Structure MyPoint
Public x As Integer
Public y As Integer
End Structure
<StructLayout(LayoutKind.Sequential, CharSet:=CharSet.Ansi)>
Friend Structure MyPerson
Public first As String
Public last As String
End Structure
<StructLayout(LayoutKind.Sequential)>
Friend Structure MyPerson2
Public person As IntPtr ' Pointer to a MyPerson structure
Public age As Integer
End Structure
<StructLayout(LayoutKind.Sequential)>
Friend Structure MyPerson3
Public person As MyPerson ' Embedded MyPerson structure
Public age As Integer
End Structure
<StructLayout(LayoutKind.Explicit)>
Friend Structure MyUnion
<FieldOffset(0)> Public i As Integer
<FieldOffset(0)> Public d As Double
End Structure
<StructLayout(LayoutKind.Sequential)>
Friend Structure MyArrayStruct
Public flag As Boolean
<MarshalAs(UnmanagedType.ByValArray, SizeConst:=3)>
Public vals As Integer()
End Structure
Prototipi di funzioni gestite
Il codice seguente mostra le DllImport dichiarazioni che espongono le funzioni non gestite da PinvokeLib.dll a codice gestito:
internal static class NativeMethods
{
[DllImport("PinvokeLib.dll", CallingConvention = CallingConvention.Cdecl)]
internal static extern int TestArrayOfInts(
[In, Out] int[] array, int size);
[DllImport("PinvokeLib.dll", CallingConvention = CallingConvention.Cdecl)]
internal static extern int TestRefArrayOfInts(
ref IntPtr array, ref int size);
[DllImport("PinvokeLib.dll", CallingConvention = CallingConvention.Cdecl)]
internal static extern int TestMatrixOfInts(
[In, Out] int[,] matrix, int row);
[DllImport("PinvokeLib.dll", CallingConvention = CallingConvention.Cdecl)]
internal static extern int TestArrayOfStrings(
[In, Out] string[] array, int size);
[DllImport("PinvokeLib.dll", CallingConvention = CallingConvention.Cdecl)]
internal static extern int TestArrayOfStructs(
[In, Out] MyPoint[] pointArray, int size);
[DllImport("PinvokeLib.dll", CallingConvention = CallingConvention.Cdecl)]
internal static extern int TestArrayOfStructs2(
[In, Out] MyPerson[] personArray, int size);
[DllImport("PinvokeLib.dll", CallingConvention = CallingConvention.Cdecl)]
internal static extern int TestStructInStruct(ref MyPerson2 person2);
[DllImport("PinvokeLib.dll", CallingConvention = CallingConvention.Cdecl)]
internal static extern void TestStructInStruct3(MyPerson3 person3);
[DllImport("PinvokeLib.dll", CallingConvention = CallingConvention.Cdecl)]
internal static extern void TestUnion(MyUnion u, int type);
[DllImport("PinvokeLib.dll", CallingConvention = CallingConvention.Cdecl)]
internal static extern void TestArrayInStruct(ref MyArrayStruct myStruct);
}
Friend Class NativeMethods
<DllImport("PinvokeLib.dll", CallingConvention:=CallingConvention.Cdecl)>
Friend Shared Function TestArrayOfInts(
<[In], Out> ByVal array() As Integer, ByVal size As Integer) As Integer
End Function
<DllImport("PinvokeLib.dll", CallingConvention:=CallingConvention.Cdecl)>
Friend Shared Function TestRefArrayOfInts(
ByRef array As IntPtr, ByRef size As Integer) As Integer
End Function
<DllImport("PinvokeLib.dll", CallingConvention:=CallingConvention.Cdecl)>
Friend Shared Function TestMatrixOfInts(
<[In], Out> ByVal matrix(,) As Integer, ByVal row As Integer) As Integer
End Function
<DllImport("PinvokeLib.dll", CallingConvention:=CallingConvention.Cdecl)>
Friend Shared Function TestArrayOfStrings(
<[In], Out> ByVal array() As String, ByVal size As Integer) As Integer
End Function
<DllImport("PinvokeLib.dll", CallingConvention:=CallingConvention.Cdecl)>
Friend Shared Function TestArrayOfStructs(
<[In], Out> ByVal pointArray() As MyPoint, ByVal size As Integer) As Integer
End Function
<DllImport("PinvokeLib.dll", CallingConvention:=CallingConvention.Cdecl)>
Friend Shared Function TestArrayOfStructs2(
<[In], Out> ByVal personArray() As MyPerson, ByVal size As Integer) As Integer
End Function
<DllImport("PinvokeLib.dll", CallingConvention:=CallingConvention.Cdecl)>
Friend Shared Function TestStructInStruct(
ByRef person2 As MyPerson2) As Integer
End Function
<DllImport("PinvokeLib.dll", CallingConvention:=CallingConvention.Cdecl)>
Friend Shared Sub TestStructInStruct3(ByVal person3 As MyPerson3)
End Sub
<DllImport("PinvokeLib.dll", CallingConvention:=CallingConvention.Cdecl)>
Friend Shared Sub TestUnion(ByVal u As MyUnion, ByVal type As Integer)
End Sub
<DllImport("PinvokeLib.dll", CallingConvention:=CallingConvention.Cdecl)>
Friend Shared Sub TestArrayInStruct(ByRef myStruct As MyArrayStruct)
End Sub
End Class
Per altre informazioni ed esempi, vedere gli articoli seguenti:
Collabora con noi su GitHub
L'origine di questo contenuto è disponibile in GitHub, in cui è anche possibile creare ed esaminare i problemi e le richieste pull. Per ulteriori informazioni, vedere la guida per i collaboratori.
