*
Windows内核下操作字符串!
*/
#include <ntddk.h>
#include <ntstrsafe.h>
#define BUFFER_SIZE 1024
VOID DriverUnload(IN PDRIVER_OBJECT pDriverObject)
{
KdPrint(("DriverUnload Load...\n"));
}
//===========================================================================
// ANSI_STRING结构和UNICODE_STRING结构的使用
#pragma code_seg("INIT")
NTSTATUS StringTest(VOID)
{
ANSI_STRING AStString = { };
UNICODE_STRING UStString2 = { };
UNICODE_STRING UStString3 = RTL_CONSTANT_STRING(L"Initialization string directly!");
CHAR *SzHello = "hello";
WCHAR *WSzHello = L"hello";
// 初始化ANSI_STRING字符串的做法
RtlInitAnsiString(&AStString, SzHello);
// %Z打印ANSI的结构字符串
KdPrint(("StringTest->ANSI_STRING: %Z\n", &AStString));
SzHello[] = 'H';
SzHello[] = 'E';
SzHello[] = 'L';
SzHello[] = 'L';
SzHello[] = 'O';
SzHello[] = '\0';
// 改变SzHello, 结构也会发生改变, ANSI_STRING里面拥有的只是指针
KdPrint(("ANSI_STRING: %Z\n", &AStString));
// 手工初始化字符串
UStString2.MaximumLength = BUFFER_SIZE; // 最大缓冲区
// 分配内存, 在分页内存中
UStString2.Buffer = (PWSTR)ExAllocatePool(PagedPool, BUFFER_SIZE);
// 设置字符长度,因为是宽字符,所以是字符长度的2倍
UStString2.Length = * wcslen(WSzHello);
// 保证缓冲区足够大, 否则程序终止
ASSERT(UStString2.MaximumLength >= UStString2.Length);
// 内存COPY, Copy的长度就是Unicode字符串的长度
RtlCopyMemory(UStString2.Buffer, WSzHello, UStString2.Length);
// 打印UnicodeString的方法%wZ
KdPrint(("StringTest->UStString2:%wZ\n", &UStString2));
KdPrint(("StringTest->UStString3:%wZ\n", &UStString3));
// 清理内存
ExFreePool(UStString2.Buffer);
UStString2.Buffer = NULL;
UStString2.Length = UStString2.MaximumLength = ;
return STATUS_SUCCESS;
}
//===========================================================================
// 字符串测试2, 字符串之间的Copy
#pragma code_seg("INIT")
NTSTATUS StringCopyTest(VOID)
{
UNICODE_STRING UStString1 = { };
UNICODE_STRING UStString2 = { };
// RtlInitUnicodeString不用释放
RtlInitUnicodeString(&UStString1, L"Hello World");
// 这样也是可以初始化的, 不过要记得释放
UStString2.Buffer = (PWSTR)ExAllocatePool(PagedPool, BUFFER_SIZE);
// Copy字符串之前必须先填写最大长度
UStString2.MaximumLength = BUFFER_SIZE;
// 将初始化UStString2拷贝到UStString1
RtlCopyUnicodeString(&UStString2, &UStString1);
// 分别显示UnicodeString1和UnicodeString2
KdPrint(("StringCopyTest->UnicodeString1:%wZ!\n", &UStString1));
KdPrint(("StringCopyTest->UnicodeString2:%wZ!\n", &UStString2));
// 字符串的连接
RtlUnicodeStringCatUnicodeString(&UStString2, &UStString1);
KdPrint(("StringCopyTest->UnicodeString2:%wZ!\n", &UStString2));
// 销毁UnicodeString2 注意!!UnicodeString1不用销毁
RtlFreeUnicodeString(&UStString2);
return STATUS_SUCCESS;
}
//===========================================================================
// 字符串的比较试验
#pragma code_seg("INIT")
VOID StringCompareTest(VOID)
{
LONG dwFlags;
UNICODE_STRING UStString1;
UNICODE_STRING UStString2;
RtlInitUnicodeString(&UStString1, L"Hello World");
RtlInitUnicodeString(&UStString2, L"Hello WorlD");
// 比较字符串, 区分大小写(FALSE), 相等返回True
if (RtlEqualUnicodeString(&UStString1, &UStString2, FALSE))
{
KdPrint(("StringCompareTest->UStString1 and UStString2 are equal\n"));
}
else
{
KdPrint(("StringCompareTest->UStString1 and UStString2 are NOT equal\n"));
}
// 比较字符串, 不区分大小写(TRUE), 相等返回TRUE
RtlInitUnicodeString(&UStString2, L"Hello World");
if (RtlEqualUnicodeString(&UStString1, &UStString2, FALSE))
{
KdPrint(("StringCompareTest->UStString1 and UStString2 are equal\n"));
}
else
{
KdPrint(("StringCompareTest->UStString1 and UStString2 are NOT equal\n"));
}
// 比较字符串, 不区分大小写(TRUE), 相等返回TRUE
RtlInitUnicodeString(&UStString2, L"Hello");
if (RtlEqualUnicodeString(&UStString1, &UStString2, TRUE))
{
KdPrint(("StringCompareTest->UStString1 and UStString2 are equal\n"));
}
else
{
KdPrint(("StringCompareTest->UStString1 and UStString2 are NOT equal\n"));
}
// 比较字符串大小, 不区分大小写(TRUE)
dwFlags = RtlCompareUnicodeString(&UStString1, &UStString2, TRUE);
if (dwFlags == )
{
KdPrint(("StringCompareTest->UStString1 == UStString2\n"));
}
else if(dwFlags > )
{
KdPrint(("StringCompareTest->UStString1 > UStString2\n"));
}
else
{
KdPrint(("StringCompareTest->UStString1 < UStString2\n"));
}
}
//===========================================================================
// 字符串转整数型试验
#pragma code_seg("INIT")
VOID StringToIntegerTest(VOID)
{
ULONG uValue;
NTSTATUS nStatus;
UNICODE_STRING UStString1 = RTL_CONSTANT_STRING(L"-100");
UNICODE_STRING UStString2={ };
// 转换正常的十进制数字
nStatus = RtlUnicodeStringToInteger(&UStString1, , &uValue);
if (NT_SUCCESS(nStatus))
{
KdPrint(("StringToIntegerTest->Conver to integer succussfully!\n"));
KdPrint(("Result:%d\n", uValue));
}
else
{
KdPrint(("StringToIntegerTest->Conver to integer unsuccessfully!\n"));
}
// 转换16进制数据
RtlInitUnicodeString(&UStString1, L"");
nStatus = RtlUnicodeStringToInteger(&UStString1, , &uValue);
if (NT_SUCCESS(nStatus))
{
KdPrint(("StringToIntegerTest->Conver to integer succussfully!"));
KdPrint(("Result:%u 0x%X \n", uValue,uValue));
}
else
{
KdPrint(("StringToIntegerTest->Conver to integer unsuccessfully!\n"));
}
// 数字转换成字符串, 初始化UnicodeString2
UStString2.Buffer = (PWSTR)ExAllocatePool(PagedPool, BUFFER_SIZE);
UStString2.MaximumLength = BUFFER_SIZE;
nStatus = RtlIntegerToUnicodeString(, , &UStString2);
if (NT_SUCCESS(nStatus))
{
KdPrint(("StringToIntegerTest->Conver to string succussfully!"));
KdPrint(("Result:%wZ\n", &UStString2));
}
else
{
KdPrint(("StringToIntegerTest->Conver to string unsuccessfully!\n"));
}
// 16进制数字转字符串
nStatus = RtlIntegerToUnicodeString(, , &UStString2);
if (NT_SUCCESS(nStatus))
{
KdPrint(("StringToIntegerTest->Conver to string succussfully!"));
KdPrint(("Result:%wZ\n", &UStString2));
}
else
{
KdPrint(("StringToIntegerTest->Conver to string unsuccessfully!\n"));
}
// UStString2, 注意!!UStString1不用销毁
RtlFreeUnicodeString(&UStString2);
}
//===========================================================================
// 字符串变大写实验
#pragma code_seg("INIT")
VOID StringToUpperTest(VOID)
{
UNICODE_STRING UStString1 = RTL_CONSTANT_STRING(L"Hello World");
// 变化前
KdPrint(("StringToUpperTest->UnicodeString1:%wZ\n", &UStString1));
// 变大写
RtlUpcaseUnicodeString(&UStString1, &UStString1, FALSE);
// 变化后
KdPrint(("StringToUpperTest->UnicodeString1:%wZ\n", &UStString1));
}
//===========================================================================
// ANSI_STRING字符串和UNICODE_STRING之间的转换
#pragma code_seg("INIT")
VOID StringConverTest(VOID)
{
ANSI_STRING StString1 = { };
UNICODE_STRING UStString2 = { };
ANSI_STRING StString2 = RTL_CONSTANT_STRING("Hello World");
UNICODE_STRING UStString1 = RTL_CONSTANT_STRING(L"Hello World");
// (1)将UNICODE_STRING字符串转换成ANSI_STRING字符串
NTSTATUS nStatus = RtlUnicodeStringToAnsiString(&StString1, &UStString1, TRUE);
if (NT_SUCCESS(nStatus))
{
KdPrint(("Conver succussfully!"));
KdPrint(("Result:%Z\n",&StString1));
}
else
{
KdPrint(("Conver unsuccessfully!\n"));
}
// 销毁AnsiString1
RtlFreeAnsiString(&StString1);
// (2)将ANSI_STRING字符串转换成UNICODE_STRING字符串初始化AnsiString2
nStatus = RtlAnsiStringToUnicodeString(&UStString2, &StString2, TRUE);
if (NT_SUCCESS(nStatus))
{
KdPrint(("Conver succussfully!\n"));
KdPrint(("Result:%wZ\n",&UStString2));
}
else
{
KdPrint(("Conver unsuccessfully!\n"));
}
// 销毁UnicodeString2
RtlFreeUnicodeString(&UStString2);
}
NTSTATUS DriverEntry(PDRIVER_OBJECT pDriverObj, PUNICODE_STRING pUSzReg)
{
pDriverObj->DriverUnload = DriverUnload;
StringTest(); // 字符串初始化试验
StringCopyTest(); // 字符串Copy试验
StringCompareTest(); // 字符串的比较试验
StringToIntegerTest(); // 字符串转整数型试验
StringToUpperTest(); // 字符串变大写实验
StringConverTest(); // ANSI和UNICODE之间的转换
return STATUS_SUCCESS;
}
