937 lines
33 KiB
C
937 lines
33 KiB
C
/* Unit test suite for Rtl* API functions
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*
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* Copyright 2003 Thomas Mertes
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*
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* This library is free software; you can redistribute it and/or
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* modify it under the terms of the GNU Lesser General Public
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* License as published by the Free Software Foundation; either
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* version 2.1 of the License, or (at your option) any later version.
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*
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* This library is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* Lesser General Public License for more details.
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*
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* You should have received a copy of the GNU Lesser General Public
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* License along with this library; if not, write to the Free Software
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* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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*
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* NOTES
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* We use function pointers here as there is no import library for NTDLL on
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* windows.
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*/
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#include <stdlib.h>
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#include "ntdll_test.h"
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#ifndef __WINE_WINTERNL_H
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typedef struct _RTL_HANDLE
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{
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struct _RTL_HANDLE * Next;
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} RTL_HANDLE;
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typedef struct _RTL_HANDLE_TABLE
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{
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ULONG MaxHandleCount;
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ULONG HandleSize;
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ULONG Unused[2];
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PVOID NextFree;
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PVOID FirstHandle;
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PVOID ReservedMemory;
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PVOID MaxHandle;
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} RTL_HANDLE_TABLE;
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#endif
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/* Function ptrs for ntdll calls */
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static HMODULE hntdll = 0;
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static SIZE_T (WINAPI *pRtlCompareMemory)(LPCVOID,LPCVOID,SIZE_T);
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static SIZE_T (WINAPI *pRtlCompareMemoryUlong)(PULONG, SIZE_T, ULONG);
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static VOID (WINAPI *pRtlMoveMemory)(LPVOID,LPCVOID,SIZE_T);
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static VOID (WINAPI *pRtlFillMemory)(LPVOID,SIZE_T,BYTE);
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static VOID (WINAPI *pRtlFillMemoryUlong)(LPVOID,SIZE_T,ULONG);
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static VOID (WINAPI *pRtlZeroMemory)(LPVOID,SIZE_T);
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static ULONGLONG (WINAPIV *pRtlUlonglongByteSwap)(ULONGLONG source);
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static ULONG (WINAPI *pRtlUniform)(PULONG);
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static ULONG (WINAPI *pRtlRandom)(PULONG);
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static BOOLEAN (WINAPI *pRtlAreAllAccessesGranted)(ACCESS_MASK, ACCESS_MASK);
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static BOOLEAN (WINAPI *pRtlAreAnyAccessesGranted)(ACCESS_MASK, ACCESS_MASK);
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static DWORD (WINAPI *pRtlComputeCrc32)(DWORD,const BYTE*,INT);
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static void (WINAPI * pRtlInitializeHandleTable)(ULONG, ULONG, RTL_HANDLE_TABLE *);
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static BOOLEAN (WINAPI * pRtlIsValidIndexHandle)(const RTL_HANDLE_TABLE *, ULONG, RTL_HANDLE **);
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static NTSTATUS (WINAPI * pRtlDestroyHandleTable)(RTL_HANDLE_TABLE *);
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static RTL_HANDLE * (WINAPI * pRtlAllocateHandle)(RTL_HANDLE_TABLE *, ULONG *);
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static BOOLEAN (WINAPI * pRtlFreeHandle)(RTL_HANDLE_TABLE *, RTL_HANDLE *);
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static NTSTATUS (WINAPI *pRtlAllocateAndInitializeSid)(PSID_IDENTIFIER_AUTHORITY,BYTE,DWORD,DWORD,DWORD,DWORD,DWORD,DWORD,DWORD,DWORD,PSID*);
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static NTSTATUS (WINAPI *pRtlFreeSid)(PSID);
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#define LEN 16
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static const char* src_src = "This is a test!"; /* 16 bytes long, incl NUL */
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static ULONG src_aligned_block[4];
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static ULONG dest_aligned_block[32];
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static const char *src = (const char*)src_aligned_block;
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static char* dest = (char*)dest_aligned_block;
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static void InitFunctionPtrs(void)
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{
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hntdll = LoadLibraryA("ntdll.dll");
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ok(hntdll != 0, "LoadLibrary failed\n");
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if (hntdll) {
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pRtlCompareMemory = (void *)GetProcAddress(hntdll, "RtlCompareMemory");
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pRtlCompareMemoryUlong = (void *)GetProcAddress(hntdll, "RtlCompareMemoryUlong");
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pRtlMoveMemory = (void *)GetProcAddress(hntdll, "RtlMoveMemory");
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pRtlFillMemory = (void *)GetProcAddress(hntdll, "RtlFillMemory");
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pRtlFillMemoryUlong = (void *)GetProcAddress(hntdll, "RtlFillMemoryUlong");
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pRtlZeroMemory = (void *)GetProcAddress(hntdll, "RtlZeroMemory");
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pRtlUlonglongByteSwap = (void *)GetProcAddress(hntdll, "RtlUlonglongByteSwap");
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pRtlUniform = (void *)GetProcAddress(hntdll, "RtlUniform");
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pRtlRandom = (void *)GetProcAddress(hntdll, "RtlRandom");
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pRtlAreAllAccessesGranted = (void *)GetProcAddress(hntdll, "RtlAreAllAccessesGranted");
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pRtlAreAnyAccessesGranted = (void *)GetProcAddress(hntdll, "RtlAreAnyAccessesGranted");
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pRtlComputeCrc32 = (void *)GetProcAddress(hntdll, "RtlComputeCrc32");
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pRtlInitializeHandleTable = (void *)GetProcAddress(hntdll, "RtlInitializeHandleTable");
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pRtlIsValidIndexHandle = (void *)GetProcAddress(hntdll, "RtlIsValidIndexHandle");
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pRtlDestroyHandleTable = (void *)GetProcAddress(hntdll, "RtlDestroyHandleTable");
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pRtlAllocateHandle = (void *)GetProcAddress(hntdll, "RtlAllocateHandle");
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pRtlFreeHandle = (void *)GetProcAddress(hntdll, "RtlFreeHandle");
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pRtlAllocateAndInitializeSid = (void *)GetProcAddress(hntdll, "RtlAllocateAndInitializeSid");
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pRtlFreeSid = (void *)GetProcAddress(hntdll, "RtlFreeSid");
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}
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strcpy((char*)src_aligned_block, src_src);
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ok(strlen(src) == 15, "Source must be 16 bytes long!\n");
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}
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#define COMP(str1,str2,cmplen,len) size = pRtlCompareMemory(str1, str2, cmplen); \
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ok(size == len, "Expected %ld, got %ld\n", size, (SIZE_T)len)
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static void test_RtlCompareMemory(void)
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{
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SIZE_T size;
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if (!pRtlCompareMemory)
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return;
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strcpy(dest, src);
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COMP(src,src,0,0);
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COMP(src,src,LEN,LEN);
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dest[0] = 'x';
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COMP(src,dest,LEN,0);
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}
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static void test_RtlCompareMemoryUlong(void)
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{
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ULONG a[10];
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ULONG result;
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a[0]= 0x0123;
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a[1]= 0x4567;
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a[2]= 0x89ab;
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a[3]= 0xcdef;
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result = pRtlCompareMemoryUlong(a, 0, 0x0123);
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ok(result == 0, "RtlCompareMemoryUlong(%p, 0, 0x0123) returns %lu, expected 0\n", a, result);
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result = pRtlCompareMemoryUlong(a, 3, 0x0123);
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ok(result == 0, "RtlCompareMemoryUlong(%p, 3, 0x0123) returns %lu, expected 0\n", a, result);
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result = pRtlCompareMemoryUlong(a, 4, 0x0123);
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ok(result == 4, "RtlCompareMemoryUlong(%p, 4, 0x0123) returns %lu, expected 4\n", a, result);
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result = pRtlCompareMemoryUlong(a, 5, 0x0123);
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ok(result == 4, "RtlCompareMemoryUlong(%p, 5, 0x0123) returns %lu, expected 4\n", a, result);
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result = pRtlCompareMemoryUlong(a, 7, 0x0123);
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ok(result == 4, "RtlCompareMemoryUlong(%p, 7, 0x0123) returns %lu, expected 4\n", a, result);
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result = pRtlCompareMemoryUlong(a, 8, 0x0123);
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ok(result == 4, "RtlCompareMemoryUlong(%p, 8, 0x0123) returns %lu, expected 4\n", a, result);
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result = pRtlCompareMemoryUlong(a, 9, 0x0123);
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ok(result == 4, "RtlCompareMemoryUlong(%p, 9, 0x0123) returns %lu, expected 4\n", a, result);
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result = pRtlCompareMemoryUlong(a, 4, 0x0127);
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ok(result == 0, "RtlCompareMemoryUlong(%p, 4, 0x0127) returns %lu, expected 0\n", a, result);
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result = pRtlCompareMemoryUlong(a, 4, 0x7123);
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ok(result == 0, "RtlCompareMemoryUlong(%p, 4, 0x7123) returns %lu, expected 0\n", a, result);
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result = pRtlCompareMemoryUlong(a, 16, 0x4567);
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ok(result == 0, "RtlCompareMemoryUlong(%p, 16, 0x4567) returns %lu, expected 0\n", a, result);
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a[1]= 0x0123;
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result = pRtlCompareMemoryUlong(a, 3, 0x0123);
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ok(result == 0, "RtlCompareMemoryUlong(%p, 3, 0x0123) returns %lu, expected 0\n", a, result);
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result = pRtlCompareMemoryUlong(a, 4, 0x0123);
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ok(result == 4, "RtlCompareMemoryUlong(%p, 4, 0x0123) returns %lu, expected 4\n", a, result);
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result = pRtlCompareMemoryUlong(a, 5, 0x0123);
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ok(result == 4, "RtlCompareMemoryUlong(%p, 5, 0x0123) returns %lu, expected 4\n", a, result);
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result = pRtlCompareMemoryUlong(a, 7, 0x0123);
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ok(result == 4, "RtlCompareMemoryUlong(%p, 7, 0x0123) returns %lu, expected 4\n", a, result);
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result = pRtlCompareMemoryUlong(a, 8, 0x0123);
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ok(result == 8, "RtlCompareMemoryUlong(%p, 8, 0x0123) returns %lu, expected 8\n", a, result);
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result = pRtlCompareMemoryUlong(a, 9, 0x0123);
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ok(result == 8, "RtlCompareMemoryUlong(%p, 9, 0x0123) returns %lu, expected 8\n", a, result);
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}
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#define COPY(len) memset(dest,0,sizeof(dest_aligned_block)); pRtlMoveMemory(dest, src, len)
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#define CMP(str) ok(strcmp(dest,str) == 0, "Expected '%s', got '%s'\n", str, dest)
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static void test_RtlMoveMemory(void)
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{
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if (!pRtlMoveMemory)
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return;
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/* Length should be in bytes and not rounded. Use strcmp to ensure we
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* didn't write past the end (it checks for the final NUL left by memset)
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*/
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COPY(0); CMP("");
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COPY(1); CMP("T");
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COPY(2); CMP("Th");
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COPY(3); CMP("Thi");
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COPY(4); CMP("This");
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COPY(5); CMP("This ");
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COPY(6); CMP("This i");
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COPY(7); CMP("This is");
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COPY(8); CMP("This is ");
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COPY(9); CMP("This is a");
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/* Overlapping */
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strcpy(dest, src); pRtlMoveMemory(dest, dest + 1, strlen(src) - 1);
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CMP("his is a test!!");
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strcpy(dest, src); pRtlMoveMemory(dest + 1, dest, strlen(src));
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CMP("TThis is a test!");
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}
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#define FILL(len) memset(dest,0,sizeof(dest_aligned_block)); strcpy(dest, src); pRtlFillMemory(dest,len,'x')
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static void test_RtlFillMemory(void)
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{
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if (!pRtlFillMemory)
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return;
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/* Length should be in bytes and not rounded. Use strcmp to ensure we
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* didn't write past the end (the remainder of the string should match)
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*/
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FILL(0); CMP("This is a test!");
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FILL(1); CMP("xhis is a test!");
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FILL(2); CMP("xxis is a test!");
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FILL(3); CMP("xxxs is a test!");
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FILL(4); CMP("xxxx is a test!");
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FILL(5); CMP("xxxxxis a test!");
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FILL(6); CMP("xxxxxxs a test!");
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FILL(7); CMP("xxxxxxx a test!");
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FILL(8); CMP("xxxxxxxxa test!");
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FILL(9); CMP("xxxxxxxxx test!");
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}
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#define LFILL(len) memset(dest,0,sizeof(dest_aligned_block)); strcpy(dest, src); pRtlFillMemoryUlong(dest,len,val)
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static void test_RtlFillMemoryUlong(void)
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{
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ULONG val = ('x' << 24) | ('x' << 16) | ('x' << 8) | 'x';
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if (!pRtlFillMemoryUlong)
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return;
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/* Length should be in bytes and not rounded. Use strcmp to ensure we
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* didn't write past the end (the remainder of the string should match)
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*/
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LFILL(0); CMP("This is a test!");
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LFILL(1); CMP("This is a test!");
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LFILL(2); CMP("This is a test!");
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LFILL(3); CMP("This is a test!");
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LFILL(4); CMP("xxxx is a test!");
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LFILL(5); CMP("xxxx is a test!");
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LFILL(6); CMP("xxxx is a test!");
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LFILL(7); CMP("xxxx is a test!");
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LFILL(8); CMP("xxxxxxxxa test!");
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LFILL(9); CMP("xxxxxxxxa test!");
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}
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#define ZERO(len) memset(dest,0,sizeof(dest_aligned_block)); strcpy(dest, src); pRtlZeroMemory(dest,len)
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#define MCMP(str) ok(memcmp(dest,str,LEN) == 0, "Memcmp failed\n")
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static void test_RtlZeroMemory(void)
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{
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if (!pRtlZeroMemory)
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return;
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/* Length should be in bytes and not rounded. */
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ZERO(0); MCMP("This is a test!");
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ZERO(1); MCMP("\0his is a test!");
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ZERO(2); MCMP("\0\0is is a test!");
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ZERO(3); MCMP("\0\0\0s is a test!");
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ZERO(4); MCMP("\0\0\0\0 is a test!");
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ZERO(5); MCMP("\0\0\0\0\0is a test!");
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ZERO(6); MCMP("\0\0\0\0\0\0s a test!");
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ZERO(7); MCMP("\0\0\0\0\0\0\0 a test!");
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ZERO(8); MCMP("\0\0\0\0\0\0\0\0a test!");
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ZERO(9); MCMP("\0\0\0\0\0\0\0\0\0 test!");
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}
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static void test_RtlUlonglongByteSwap(void)
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{
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ULONGLONG result;
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result = pRtlUlonglongByteSwap( ((ULONGLONG)0x76543210 << 32) | 0x87654321 );
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ok( (((ULONGLONG)0x21436587 << 32) | 0x10325476) == result,
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"RtlUlonglongByteSwap(0x7654321087654321) returns 0x%llx, expected 0x2143658710325476\n",
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result);
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}
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static void test_RtlUniform(void)
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{
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ULONGLONG num;
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ULONG seed;
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ULONG seed_bak;
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ULONG expected;
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ULONG result;
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/*
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* According to the documentation RtlUniform is using D.H. Lehmer's 1948
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* algorithm. This algorithm is:
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*
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* seed = (seed * const_1 + const_2) % const_3;
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*
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* According to the documentation the random number is distributed over
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* [0..MAXLONG]. Therefore const_3 is MAXLONG + 1:
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*
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* seed = (seed * const_1 + const_2) % (MAXLONG + 1);
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*
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* Because MAXLONG is 0x7fffffff (and MAXLONG + 1 is 0x80000000) the
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* algorithm can be expressed without division as:
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*
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* seed = (seed * const_1 + const_2) & MAXLONG;
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*
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* To find out const_2 we just call RtlUniform with seed set to 0:
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*/
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seed = 0;
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expected = 0x7fffffc3;
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result = pRtlUniform(&seed);
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ok(result == expected,
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"RtlUniform(&seed (seed == 0)) returns %lx, expected %lx\n",
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result, expected);
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/*
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* The algorithm is now:
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*
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* seed = (seed * const_1 + 0x7fffffc3) & MAXLONG;
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*
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* To find out const_1 we can use:
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*
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* const_1 = RtlUniform(1) - 0x7fffffc3;
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*
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* If that does not work a search loop can try all possible values of
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* const_1 and compare to the result to RtlUniform(1).
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* This way we find out that const_1 is 0xffffffed.
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*
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* For seed = 1 the const_2 is 0x7fffffc4:
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*/
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seed = 1;
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expected = seed * 0xffffffed + 0x7fffffc3 + 1;
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result = pRtlUniform(&seed);
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ok(result == expected,
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"RtlUniform(&seed (seed == 1)) returns %lx, expected %lx\n",
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result, expected);
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/*
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* For seed = 2 the const_2 is 0x7fffffc3:
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*/
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seed = 2;
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expected = seed * 0xffffffed + 0x7fffffc3;
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result = pRtlUniform(&seed);
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ok(result == expected,
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"RtlUniform(&seed (seed == 2)) returns %lx, expected %lx\n",
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result, expected);
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/*
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* More tests show that if seed is odd the result must be incremented by 1:
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*/
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seed = 3;
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expected = seed * 0xffffffed + 0x7fffffc3 + (seed & 1);
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result = pRtlUniform(&seed);
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ok(result == expected,
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"RtlUniform(&seed (seed == 2)) returns %lx, expected %lx\n",
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result, expected);
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seed = 0x6bca1aa;
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expected = seed * 0xffffffed + 0x7fffffc3;
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result = pRtlUniform(&seed);
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ok(result == expected,
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"RtlUniform(&seed (seed == 0x6bca1aa)) returns %lx, expected %lx\n",
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result, expected);
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seed = 0x6bca1ab;
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expected = seed * 0xffffffed + 0x7fffffc3 + 1;
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result = pRtlUniform(&seed);
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ok(result == expected,
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"RtlUniform(&seed (seed == 0x6bca1ab)) returns %lx, expected %lx\n",
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result, expected);
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/*
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* When seed is 0x6bca1ac there is an exception:
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*/
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seed = 0x6bca1ac;
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expected = seed * 0xffffffed + 0x7fffffc3 + 2;
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result = pRtlUniform(&seed);
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ok(result == expected,
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"RtlUniform(&seed (seed == 0x6bca1ac)) returns %lx, expected %lx\n",
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result, expected);
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/*
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* Note that up to here const_3 is not used
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* (the highest bit of the result is not set).
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*
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* Starting with 0x6bca1ad: If seed is even the result must be incremented by 1:
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*/
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seed = 0x6bca1ad;
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expected = (seed * 0xffffffed + 0x7fffffc3) & MAXLONG;
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result = pRtlUniform(&seed);
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ok(result == expected,
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"RtlUniform(&seed (seed == 0x6bca1ad)) returns %lx, expected %lx\n",
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result, expected);
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seed = 0x6bca1ae;
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expected = (seed * 0xffffffed + 0x7fffffc3 + 1) & MAXLONG;
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result = pRtlUniform(&seed);
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ok(result == expected,
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"RtlUniform(&seed (seed == 0x6bca1ae)) returns %lx, expected %lx\n",
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result, expected);
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/*
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* There are several ranges where for odd or even seed the result must be
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* incremented by 1. You can see this ranges in the following test.
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*
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* For a full test use one of the following loop heads:
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*
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* for (num = 0; num <= 0xffffffff; num++) {
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* seed = num;
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* ...
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*
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* seed = 0;
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* for (num = 0; num <= 0xffffffff; num++) {
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* ...
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*/
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seed = 0;
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for (num = 0; num <= 100000; num++) {
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expected = seed * 0xffffffed + 0x7fffffc3;
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if (seed < 0x6bca1ac) {
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expected = expected + (seed & 1);
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} else if (seed == 0x6bca1ac) {
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expected = (expected + 2) & MAXLONG;
|
|
} else if (seed < 0xd79435c) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0x1435e50b) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0x1af286ba) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0x21af2869) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0x286bca18) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0x2f286bc7) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0x35e50d77) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0x3ca1af26) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0x435e50d5) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0x4a1af284) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0x50d79433) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0x579435e2) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0x5e50d792) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0x650d7941) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0x6bca1af0) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0x7286bc9f) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0x79435e4e) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0x7ffffffd) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0x86bca1ac) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed == 0x86bca1ac) {
|
|
expected = (expected + 1) & MAXLONG;
|
|
} else if (seed < 0x8d79435c) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0x9435e50b) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0x9af286ba) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0xa1af2869) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0xa86bca18) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0xaf286bc7) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed == 0xaf286bc7) {
|
|
expected = (expected + 2) & MAXLONG;
|
|
} else if (seed < 0xb5e50d77) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0xbca1af26) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0xc35e50d5) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0xca1af284) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0xd0d79433) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0xd79435e2) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0xde50d792) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0xe50d7941) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0xebca1af0) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0xf286bc9f) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else if (seed < 0xf9435e4e) {
|
|
expected = expected + (seed & 1);
|
|
} else if (seed < 0xfffffffd) {
|
|
expected = (expected + (~seed & 1)) & MAXLONG;
|
|
} else {
|
|
expected = expected + (seed & 1);
|
|
} /* if */
|
|
seed_bak = seed;
|
|
result = pRtlUniform(&seed);
|
|
ok(result == expected,
|
|
"test: %llu RtlUniform(&seed (seed == %lx)) returns %lx, expected %lx\n",
|
|
num, seed_bak, result, expected);
|
|
ok(seed == expected,
|
|
"test: %llu RtlUniform(&seed (seed == %lx)) sets seed to %lx, expected %lx\n",
|
|
num, seed_bak, seed, expected);
|
|
} /* for */
|
|
/*
|
|
* Further investigation shows: In the different regions the highest bit
|
|
* is set or cleared when even or odd seeds need an increment by 1.
|
|
* This leads to a simplified algorithm:
|
|
*
|
|
* seed = seed * 0xffffffed + 0x7fffffc3;
|
|
* if (seed == 0xffffffff || seed == 0x7ffffffe) {
|
|
* seed = (seed + 2) & MAXLONG;
|
|
* } else if (seed == 0x7fffffff) {
|
|
* seed = 0;
|
|
* } else if ((seed & 0x80000000) == 0) {
|
|
* seed = seed + (~seed & 1);
|
|
* } else {
|
|
* seed = (seed + (seed & 1)) & MAXLONG;
|
|
* }
|
|
*
|
|
* This is also the algorithm used for RtlUniform of wine (see dlls/ntdll/rtl.c).
|
|
*
|
|
* Now comes the funny part:
|
|
* It took me one weekend, to find the complicated algorithm and one day more,
|
|
* to find the simplified algorithm. Several weeks later I found out: The value
|
|
* MAXLONG (=0x7fffffff) is never returned, neither with the native function
|
|
* nor with the simplified algorithm. In reality the native function and our
|
|
* function return a random number distributed over [0..MAXLONG-1]. Note
|
|
* that this is different from what native documentation states [0..MAXLONG].
|
|
* Expressed with D.H. Lehmer's 1948 algorithm it looks like:
|
|
*
|
|
* seed = (seed * const_1 + const_2) % MAXLONG;
|
|
*
|
|
* Further investigations show that the real algorithm is:
|
|
*
|
|
* seed = (seed * 0x7fffffed + 0x7fffffc3) % MAXLONG;
|
|
*
|
|
* This is checked with the test below:
|
|
*/
|
|
seed = 0;
|
|
for (num = 0; num <= 100000; num++) {
|
|
expected = (seed * 0x7fffffed + 0x7fffffc3) % 0x7fffffff;
|
|
seed_bak = seed;
|
|
result = pRtlUniform(&seed);
|
|
ok(result == expected,
|
|
"test: %llu RtlUniform(&seed (seed == %lx)) returns %lx, expected %lx\n",
|
|
num, seed_bak, result, expected);
|
|
ok(seed == expected,
|
|
"test: %llu RtlUniform(&seed (seed == %lx)) sets seed to %lx, expected %lx\n",
|
|
num, seed_bak, seed, expected);
|
|
} /* for */
|
|
/*
|
|
* More tests show that RtlUniform does not return 0x7ffffffd for seed values
|
|
* in the range [0..MAXLONG-1]. Additionally 2 is returned twice. This shows
|
|
* that there is more than one cycle of generated randon numbers ...
|
|
*/
|
|
}
|
|
|
|
|
|
static ULONG WINAPI my_RtlRandom(PULONG seed)
|
|
{
|
|
static ULONG saved_value[128] =
|
|
{ /* 0 */ 0x4c8bc0aa, 0x4c022957, 0x2232827a, 0x2f1e7626, 0x7f8bdafb, 0x5c37d02a, 0x0ab48f72, 0x2f0c4ffa,
|
|
/* 8 */ 0x290e1954, 0x6b635f23, 0x5d3885c0, 0x74b49ff8, 0x5155fa54, 0x6214ad3f, 0x111e9c29, 0x242a3a09,
|
|
/* 16 */ 0x75932ae1, 0x40ac432e, 0x54f7ba7a, 0x585ccbd5, 0x6df5c727, 0x0374dad1, 0x7112b3f1, 0x735fc311,
|
|
/* 24 */ 0x404331a9, 0x74d97781, 0x64495118, 0x323e04be, 0x5974b425, 0x4862e393, 0x62389c1d, 0x28a68b82,
|
|
/* 32 */ 0x0f95da37, 0x7a50bbc6, 0x09b0091c, 0x22cdb7b4, 0x4faaed26, 0x66417ccd, 0x189e4bfa, 0x1ce4e8dd,
|
|
/* 40 */ 0x5274c742, 0x3bdcf4dc, 0x2d94e907, 0x32eac016, 0x26d33ca3, 0x60415a8a, 0x31f57880, 0x68c8aa52,
|
|
/* 48 */ 0x23eb16da, 0x6204f4a1, 0x373927c1, 0x0d24eb7c, 0x06dd7379, 0x2b3be507, 0x0f9c55b1, 0x2c7925eb,
|
|
/* 56 */ 0x36d67c9a, 0x42f831d9, 0x5e3961cb, 0x65d637a8, 0x24bb3820, 0x4d08e33d, 0x2188754f, 0x147e409e,
|
|
/* 64 */ 0x6a9620a0, 0x62e26657, 0x7bd8ce81, 0x11da0abb, 0x5f9e7b50, 0x23e444b6, 0x25920c78, 0x5fc894f0,
|
|
/* 72 */ 0x5e338cbb, 0x404237fd, 0x1d60f80f, 0x320a1743, 0x76013d2b, 0x070294ee, 0x695e243b, 0x56b177fd,
|
|
/* 80 */ 0x752492e1, 0x6decd52f, 0x125f5219, 0x139d2e78, 0x1898d11e, 0x2f7ee785, 0x4db405d8, 0x1a028a35,
|
|
/* 88 */ 0x63f6f323, 0x1f6d0078, 0x307cfd67, 0x3f32a78a, 0x6980796c, 0x462b3d83, 0x34b639f2, 0x53fce379,
|
|
/* 96 */ 0x74ba50f4, 0x1abc2c4b, 0x5eeaeb8d, 0x335a7a0d, 0x3973dd20, 0x0462d66b, 0x159813ff, 0x1e4643fd,
|
|
/* 104 */ 0x06bc5c62, 0x3115e3fc, 0x09101613, 0x47af2515, 0x4f11ec54, 0x78b99911, 0x3db8dd44, 0x1ec10b9b,
|
|
/* 112 */ 0x5b5506ca, 0x773ce092, 0x567be81a, 0x5475b975, 0x7a2cde1a, 0x494536f5, 0x34737bb4, 0x76d9750b,
|
|
/* 120 */ 0x2a1f6232, 0x2e49644d, 0x7dddcbe7, 0x500cebdb, 0x619dab9e, 0x48c626fe, 0x1cda3193, 0x52dabe9d };
|
|
ULONG rand;
|
|
int pos;
|
|
ULONG result;
|
|
|
|
rand = (*seed * 0x7fffffed + 0x7fffffc3) % 0x7fffffff;
|
|
*seed = (rand * 0x7fffffed + 0x7fffffc3) % 0x7fffffff;
|
|
pos = *seed & 0x7f;
|
|
result = saved_value[pos];
|
|
saved_value[pos] = rand;
|
|
return(result);
|
|
}
|
|
|
|
|
|
static void test_RtlRandom(void)
|
|
{
|
|
ULONGLONG num;
|
|
ULONG seed;
|
|
ULONG seed_bak;
|
|
ULONG seed_expected;
|
|
ULONG result;
|
|
ULONG result_expected;
|
|
|
|
/*
|
|
* Unlike RtlUniform, RtlRandom is not documented. We guess that for
|
|
* RtlRandom D.H. Lehmer's 1948 algorithm is used like stated in
|
|
* the documentation of the RtlUniform function. This algorithm is:
|
|
*
|
|
* seed = (seed * const_1 + const_2) % const_3;
|
|
*
|
|
* According to the RtlUniform documentation the random number is
|
|
* distributed over [0..MAXLONG], but in reality it is distributed
|
|
* over [0..MAXLONG-1]. Therefore const_3 might be MAXLONG + 1 or
|
|
* MAXLONG:
|
|
*
|
|
* seed = (seed * const_1 + const_2) % (MAXLONG + 1);
|
|
*
|
|
* or
|
|
*
|
|
* seed = (seed * const_1 + const_2) % MAXLONG;
|
|
*
|
|
* To find out const_2 we just call RtlRandom with seed set to 0:
|
|
*/
|
|
seed = 0;
|
|
result_expected = 0x320a1743;
|
|
seed_expected =0x44b;
|
|
result = pRtlRandom(&seed);
|
|
ok(result == result_expected,
|
|
"pRtlRandom(&seed (seed == 0)) returns %lx, expected %lx\n",
|
|
result, result_expected);
|
|
ok(seed == seed_expected,
|
|
"pRtlRandom(&seed (seed == 0)) sets seed to %lx, expected %lx\n",
|
|
seed, seed_expected);
|
|
/*
|
|
* Seed is not equal to result as with RtlUniform. To see more we
|
|
* call RtlRandom aggain with seed set to 0:
|
|
*/
|
|
seed = 0;
|
|
result_expected = 0x7fffffc3;
|
|
seed_expected =0x44b;
|
|
result = pRtlRandom(&seed);
|
|
ok(result == result_expected,
|
|
"RtlRandom(&seed (seed == 0)) returns %lx, expected %lx\n",
|
|
result, result_expected);
|
|
ok(seed == seed_expected,
|
|
"RtlRandom(&seed (seed == 0)) sets seed to %lx, expected %lx\n",
|
|
seed, seed_expected);
|
|
/*
|
|
* Seed is set to the same value as before but the result is different.
|
|
* To see more we call RtlRandom aggain with seed set to 0:
|
|
*/
|
|
seed = 0;
|
|
result_expected = 0x7fffffc3;
|
|
seed_expected =0x44b;
|
|
result = pRtlRandom(&seed);
|
|
ok(result == result_expected,
|
|
"RtlRandom(&seed (seed == 0)) returns %lx, expected %lx\n",
|
|
result, result_expected);
|
|
ok(seed == seed_expected,
|
|
"RtlRandom(&seed (seed == 0)) sets seed to %lx, expected %lx\n",
|
|
seed, seed_expected);
|
|
/*
|
|
* Seed is aggain set to the same value as before. This time we also
|
|
* have the same result as before. Interestingly the value of the
|
|
* result is 0x7fffffc3 which is the same value used in RtlUniform
|
|
* as const_2. If we do
|
|
*
|
|
* seed = 0;
|
|
* result = RtlUniform(&seed);
|
|
*
|
|
* we get the same result (0x7fffffc3) as with
|
|
*
|
|
* seed = 0;
|
|
* RtlRandom(&seed);
|
|
* seed = 0;
|
|
* result = RtlRandom(&seed);
|
|
*
|
|
* And there is another interesting thing. If we do
|
|
*
|
|
* seed = 0;
|
|
* RtlUniform(&seed);
|
|
* RtlUniform(&seed);
|
|
*
|
|
* seed is set to the value 0x44b which ist the same value that
|
|
*
|
|
* seed = 0;
|
|
* RtlRandom(&seed);
|
|
*
|
|
* assigns to seed. Putting these two findings together leads to
|
|
* the concluson that RtlRandom saves the value in some variable,
|
|
* like in the following algorithm:
|
|
*
|
|
* result = saved_value;
|
|
* saved_value = RtlUniform(&seed);
|
|
* RtlUniform(&seed);
|
|
* return(result);
|
|
*
|
|
* Now we do further tests with seed set to 1:
|
|
*/
|
|
seed = 1;
|
|
result_expected = 0x7a50bbc6;
|
|
seed_expected =0x5a1;
|
|
result = pRtlRandom(&seed);
|
|
ok(result == result_expected,
|
|
"RtlRandom(&seed (seed == 1)) returns %lx, expected %lx\n",
|
|
result, result_expected);
|
|
ok(seed == seed_expected,
|
|
"RtlRandom(&seed (seed == 1)) sets seed to %lx, expected %lx\n",
|
|
seed, seed_expected);
|
|
/*
|
|
* If there is just one saved_value the result now would be
|
|
* 0x7fffffc3. From this test we can see that there is more than
|
|
* one saved_value, like with this algorithm:
|
|
*
|
|
* result = saved_value[pos];
|
|
* saved_value[pos] = RtlUniform(&seed);
|
|
* RtlUniform(&seed);
|
|
* return(result);
|
|
*
|
|
* But how is the value of pos determined? The calls to RtlUniform
|
|
* create a sequence of random numbers. Every second random number
|
|
* is put into the saved_value array and is used in some later call
|
|
* of RtlRandom as result. The only reasonable source to determine
|
|
* pos are the random numbers generated by RtlUniform which are not
|
|
* put into the saved_value array. This are the values of seed
|
|
* between the two calls of RtlUniform as in this algorithm:
|
|
*
|
|
* rand = RtlUniform(&seed);
|
|
* RtlUniform(&seed);
|
|
* pos = position(seed);
|
|
* result = saved_value[pos];
|
|
* saved_value[pos] = rand;
|
|
* return(result);
|
|
*
|
|
* What remains to be determined is: The size of the saved_value array,
|
|
* the initial values of the saved_value array and the function
|
|
* position(seed). These tests are not shown here.
|
|
* The result of these tests is: The size of the saved_value array
|
|
* is 128, the initial values can be seen in the my_RtlRandom
|
|
* function and the position(seed) function is (seed & 0x7f).
|
|
*
|
|
* For a full test of RtlRandom use one of the following loop heads:
|
|
*
|
|
* for (num = 0; num <= 0xffffffff; num++) {
|
|
* seed = num;
|
|
* ...
|
|
*
|
|
* seed = 0;
|
|
* for (num = 0; num <= 0xffffffff; num++) {
|
|
* ...
|
|
*/
|
|
seed = 0;
|
|
for (num = 0; num <= 100000; num++) {
|
|
seed_bak = seed;
|
|
seed_expected = seed;
|
|
result_expected = my_RtlRandom(&seed_expected);
|
|
/* The following corrections are necessary because the */
|
|
/* previous tests changed the saved_value array */
|
|
if (num == 0) {
|
|
result_expected = 0x7fffffc3;
|
|
} else if (num == 81) {
|
|
result_expected = 0x7fffffb1;
|
|
} /* if */
|
|
result = pRtlRandom(&seed);
|
|
ok(result == result_expected,
|
|
"test: %llu RtlUniform(&seed (seed == %lx)) returns %lx, expected %lx\n",
|
|
num, seed_bak, result, result_expected);
|
|
ok(seed == seed_expected,
|
|
"test: %llu RtlUniform(&seed (seed == %lx)) sets seed to %lx, expected %lx\n",
|
|
num, seed_bak, seed, seed_expected);
|
|
} /* for */
|
|
}
|
|
|
|
|
|
typedef struct {
|
|
ACCESS_MASK GrantedAccess;
|
|
ACCESS_MASK DesiredAccess;
|
|
BOOLEAN result;
|
|
} all_accesses_t;
|
|
|
|
static const all_accesses_t all_accesses[] = {
|
|
{0xFEDCBA76, 0xFEDCBA76, 1},
|
|
{0x00000000, 0xFEDCBA76, 0},
|
|
{0xFEDCBA76, 0x00000000, 1},
|
|
{0x00000000, 0x00000000, 1},
|
|
{0xFEDCBA76, 0xFEDCBA70, 1},
|
|
{0xFEDCBA70, 0xFEDCBA76, 0},
|
|
{0xFEDCBA76, 0xFEDC8A76, 1},
|
|
{0xFEDC8A76, 0xFEDCBA76, 0},
|
|
{0xFEDCBA76, 0xC8C4B242, 1},
|
|
{0xC8C4B242, 0xFEDCBA76, 0},
|
|
};
|
|
#define NB_ALL_ACCESSES (sizeof(all_accesses)/sizeof(*all_accesses))
|
|
|
|
|
|
static void test_RtlAreAllAccessesGranted(void)
|
|
{
|
|
size_t test_num;
|
|
BOOLEAN result;
|
|
|
|
for (test_num = 0; test_num < NB_ALL_ACCESSES; test_num++) {
|
|
result = pRtlAreAllAccessesGranted(all_accesses[test_num].GrantedAccess,
|
|
all_accesses[test_num].DesiredAccess);
|
|
ok(all_accesses[test_num].result == result,
|
|
"(test %d): RtlAreAllAccessesGranted(%08lx, %08lx) returns %d, expected %d\n",
|
|
test_num, all_accesses[test_num].GrantedAccess,
|
|
all_accesses[test_num].DesiredAccess,
|
|
result, all_accesses[test_num].result);
|
|
} /* for */
|
|
}
|
|
|
|
|
|
typedef struct {
|
|
ACCESS_MASK GrantedAccess;
|
|
ACCESS_MASK DesiredAccess;
|
|
BOOLEAN result;
|
|
} any_accesses_t;
|
|
|
|
static const any_accesses_t any_accesses[] = {
|
|
{0xFEDCBA76, 0xFEDCBA76, 1},
|
|
{0x00000000, 0xFEDCBA76, 0},
|
|
{0xFEDCBA76, 0x00000000, 0},
|
|
{0x00000000, 0x00000000, 0},
|
|
{0xFEDCBA76, 0x01234589, 0},
|
|
{0x00040000, 0xFEDCBA76, 1},
|
|
{0x00040000, 0xFED8BA76, 0},
|
|
{0xFEDCBA76, 0x00040000, 1},
|
|
{0xFED8BA76, 0x00040000, 0},
|
|
};
|
|
#define NB_ANY_ACCESSES (sizeof(any_accesses)/sizeof(*any_accesses))
|
|
|
|
|
|
static void test_RtlAreAnyAccessesGranted(void)
|
|
{
|
|
size_t test_num;
|
|
BOOLEAN result;
|
|
|
|
for (test_num = 0; test_num < NB_ANY_ACCESSES; test_num++) {
|
|
result = pRtlAreAnyAccessesGranted(any_accesses[test_num].GrantedAccess,
|
|
any_accesses[test_num].DesiredAccess);
|
|
ok(any_accesses[test_num].result == result,
|
|
"(test %d): RtlAreAnyAccessesGranted(%08lx, %08lx) returns %d, expected %d\n",
|
|
test_num, any_accesses[test_num].GrantedAccess,
|
|
any_accesses[test_num].DesiredAccess,
|
|
result, any_accesses[test_num].result);
|
|
} /* for */
|
|
}
|
|
|
|
static void test_RtlComputeCrc32(void)
|
|
{
|
|
DWORD crc = 0;
|
|
|
|
if (!pRtlComputeCrc32)
|
|
return;
|
|
|
|
crc = pRtlComputeCrc32(crc, (LPBYTE)src, LEN);
|
|
ok(crc == 0x40861dc2,"Expected 0x40861dc2, got %8lx\n", crc);
|
|
}
|
|
|
|
|
|
typedef struct MY_HANDLE
|
|
{
|
|
RTL_HANDLE RtlHandle;
|
|
void * MyValue;
|
|
} MY_HANDLE;
|
|
|
|
static inline void RtlpMakeHandleAllocated(RTL_HANDLE * Handle)
|
|
{
|
|
ULONG_PTR *AllocatedBit = (ULONG_PTR *)(&Handle->Next);
|
|
*AllocatedBit = *AllocatedBit | 1;
|
|
}
|
|
|
|
static void test_HandleTables(void)
|
|
{
|
|
BOOLEAN result;
|
|
NTSTATUS status;
|
|
ULONG Index;
|
|
MY_HANDLE * MyHandle;
|
|
RTL_HANDLE_TABLE HandleTable;
|
|
|
|
pRtlInitializeHandleTable(0x3FFF, sizeof(MY_HANDLE), &HandleTable);
|
|
MyHandle = (MY_HANDLE *)pRtlAllocateHandle(&HandleTable, &Index);
|
|
ok(MyHandle != NULL, "RtlAllocateHandle failed\n");
|
|
RtlpMakeHandleAllocated(&MyHandle->RtlHandle);
|
|
MyHandle = NULL;
|
|
result = pRtlIsValidIndexHandle(&HandleTable, Index, (RTL_HANDLE **)&MyHandle);
|
|
ok(result, "Handle %p wasn't valid\n", MyHandle);
|
|
result = pRtlFreeHandle(&HandleTable, &MyHandle->RtlHandle);
|
|
ok(result, "Couldn't free handle %p\n", MyHandle);
|
|
status = pRtlDestroyHandleTable(&HandleTable);
|
|
ok(status == STATUS_SUCCESS, "RtlDestroyHandleTable failed with error 0x%08lx\n", status);
|
|
}
|
|
|
|
static void test_RtlAllocateAndInitializeSid(void)
|
|
{
|
|
NTSTATUS ret;
|
|
SID_IDENTIFIER_AUTHORITY sia = {{ 1, 2, 3, 4, 5, 6 }};
|
|
PSID psid;
|
|
|
|
ret = pRtlAllocateAndInitializeSid(&sia, 0, 1, 2, 3, 4, 5, 6, 7, 8, &psid);
|
|
ok(!ret, "RtlAllocateAndInitializeSid error %08lx\n", ret);
|
|
ret = pRtlFreeSid(psid);
|
|
ok(!ret, "RtlFreeSid error %08lx\n", ret);
|
|
|
|
/* these tests crash on XP
|
|
ret = pRtlAllocateAndInitializeSid(NULL, 0, 1, 2, 3, 4, 5, 6, 7, 8, &psid);
|
|
ret = pRtlAllocateAndInitializeSid(&sia, 0, 1, 2, 3, 4, 5, 6, 7, 8, NULL);*/
|
|
|
|
ret = pRtlAllocateAndInitializeSid(&sia, 9, 1, 2, 3, 4, 5, 6, 7, 8, &psid);
|
|
ok(ret == STATUS_INVALID_SID, "wrong error %08lx\n", ret);
|
|
}
|
|
|
|
START_TEST(rtl)
|
|
{
|
|
InitFunctionPtrs();
|
|
|
|
if (pRtlCompareMemory)
|
|
test_RtlCompareMemory();
|
|
if (pRtlCompareMemoryUlong)
|
|
test_RtlCompareMemoryUlong();
|
|
if (pRtlMoveMemory)
|
|
test_RtlMoveMemory();
|
|
if (pRtlFillMemory)
|
|
test_RtlFillMemory();
|
|
if (pRtlFillMemoryUlong)
|
|
test_RtlFillMemoryUlong();
|
|
if (pRtlZeroMemory)
|
|
test_RtlZeroMemory();
|
|
if (pRtlUlonglongByteSwap)
|
|
test_RtlUlonglongByteSwap();
|
|
if (pRtlUniform)
|
|
test_RtlUniform();
|
|
if (pRtlRandom)
|
|
test_RtlRandom();
|
|
if (pRtlAreAllAccessesGranted)
|
|
test_RtlAreAllAccessesGranted();
|
|
if (pRtlAreAnyAccessesGranted)
|
|
test_RtlAreAnyAccessesGranted();
|
|
if (pRtlComputeCrc32)
|
|
test_RtlComputeCrc32();
|
|
if (pRtlInitializeHandleTable)
|
|
test_HandleTables();
|
|
if (pRtlAllocateAndInitializeSid)
|
|
test_RtlAllocateAndInitializeSid();
|
|
}
|