/* * VARIANT test program * * Copyright 1998 Jean-Claude Cote * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include #include #include #include #include #include "windef.h" #include "winbase.h" #include "winsock.h" #include "wine/test.h" #include "winuser.h" #include "wingdi.h" #include "winnls.h" #include "winerror.h" #include "winnt.h" #include "wtypes.h" #include "oleauto.h" static HMODULE hOleaut32; static HRESULT (WINAPI *pVarUdateFromDate)(DATE,ULONG,UDATE*); static HRESULT (WINAPI *pVarDateFromUdate)(UDATE*,ULONG,DATE*); static INT (WINAPI *pSystemTimeToVariantTime)(LPSYSTEMTIME,double*); static INT (WINAPI *pVariantTimeToSystemTime)(double,LPSYSTEMTIME); static INT (WINAPI *pDosDateTimeToVariantTime)(USHORT,USHORT,double*); static INT (WINAPI *pVariantTimeToDosDateTime)(double,USHORT*,USHORT *); static HRESULT (WINAPI *pVarFormatNumber)(LPVARIANT,int,int,int,int,ULONG,BSTR*); static HRESULT (WINAPI *pVarFormat)(LPVARIANT,LPOLESTR,int,int,ULONG,BSTR*); /* Get a conversion function ptr, return if function not available */ #define CHECKPTR(func) p##func = (void*)GetProcAddress(hOleaut32, #func); \ if (!p##func) { trace("function " # func " not available, not testing it\n"); return; } /* Is a given function exported from oleaut32? */ #define HAVE_FUNC(func) ((void*)GetProcAddress(hOleaut32, #func) != NULL) /* Have IRecordInfo data type? */ #define HAVE_OLEAUT32_RECORD HAVE_FUNC(SafeArraySetRecordInfo) /* Have CY data type? */ #define HAVE_OLEAUT32_CY HAVE_FUNC(VarCyAdd) /* Have I8/UI8 data type? */ #define HAVE_OLEAUT32_I8 HAVE_FUNC(VarI8FromI1) /* Is this an ancient version with support for only I2/I4/R4/R8/DATE? */ #define IS_ANCIENT (!HAVE_FUNC(VarI1FromI2)) /* When comparing floating point values we cannot expect an exact match * because the rounding errors depend on the exact algorithm. */ #define EQ_DOUBLE(a,b) (fabs((a)-(b))<1e-14) #define EQ_FLOAT(a,b) (fabs((a)-(b))<1e-7) #define SKIPTESTS(a) if((a > VT_CLSID+10) && (a < VT_BSTR_BLOB-10)) continue; /* Allow our test macros to work for VT_NULL and VT_EMPTY too */ #define V_EMPTY(v) V_I4(v) #define V_NULL(v) V_I4(v) /* Size constraints for overflow tests */ #define I1_MAX 0x7f #define I1_MIN ((-I1_MAX)-1) #define UI1_MAX 0xff #define UI1_MIN 0 #define I2_MAX 0x7fff #define I2_MIN ((-I2_MAX)-1) #define UI2_MAX 0xffff #define UI2_MIN 0 #define I4_MAX 0x7fffffff #define I4_MIN ((-I4_MAX)-1) #define UI4_MAX 0xffffffff #define UI4_MIN 0 #define I8_MAX (((LONGLONG)I4_MAX << 32) | UI4_MAX) #define I8_MIN ((-I8_MAX)-1) #define UI8_MAX (((ULONGLONG)UI4_MAX << 32) | UI4_MAX) #define UI8_MIN 0 #define DATE_MAX 2958465 #define DATE_MIN -657434 #define R4_MAX FLT_MAX #define R4_MIN FLT_MIN #define R8_MAX DBL_MAX #define R8_MIN DBL_MIN static inline int strcmpW( const WCHAR *str1, const WCHAR *str2 ) { while (*str1 && (*str1 == *str2)) { str1++; str2++; } return *str1 - *str2; } /* return the string text of a given variant type */ static const char *vtstr(int x) { switch(x) { case 0: return "VT_EMPTY"; case 1: return "VT_NULL"; case 2: return "VT_I2"; case 3: return "VT_I4"; case 4: return "VT_R4"; case 5: return "VT_R8"; case 6: return "VT_CY"; case 7: return "VT_DATE"; case 8: return "VT_BSTR"; case 9: return "VT_DISPATCH"; case 10: return "VT_ERROR"; case 11: return "VT_BOOL"; case 12: return "VT_VARIANT"; case 13: return "VT_UNKNOWN"; case 14: return "VT_DECIMAL"; case 15: return "notdefined"; case 16: return "VT_I1"; case 17: return "VT_UI1"; case 18: return "VT_UI2"; case 19: return "VT_UI4"; case 20: return "VT_I8"; case 21: return "VT_UI8"; case 22: return "VT_INT"; case 23: return "VT_UINT"; case 24: return "VT_VOID"; case 25: return "VT_HRESULT"; case 26: return "VT_PTR"; case 27: return "VT_SAFEARRAY"; case 28: return "VT_CARRAY"; case 29: return "VT_USERDEFINED"; case 30: return "VT_LPSTR"; case 31: return "VT_LPWSTR"; case 36: return "VT_RECORD"; case 64: return "VT_FILETIME"; case 65: return "VT_BLOB"; case 66: return "VT_STREAM"; case 67: return "VT_STORAGE"; case 68: return "VT_STREAMED_OBJECT"; case 69: return "VT_STORED_OBJECT"; case 70: return "VT_BLOB_OBJECT"; case 71: return "VT_CF"; case 72: return "VT_CLSID"; case 0xFFF: return "VT_BSTR_BLOB/VT_ILLEGALMASKED/VT_TYPEMASK"; case 0x1000: return "VT_VECTOR"; case 0x2000: return "VT_ARRAY"; case 0x4000: return "VT_BYREF"; case 0x8000: return "VT_BYREF"; case 0xFFFF: return "VT_ILLEGAL"; default: return "defineme"; } } static void test_VariantInit(void) { VARIANTARG v1, v2; /* Test that VariantInit() only sets the type */ memset(&v1, -1, sizeof(v1)); v2 = v1; V_VT(&v2) = VT_EMPTY; VariantInit(&v1); ok(!memcmp(&v1, &v2, sizeof(v1)), "VariantInit() set extra fields\n"); } /* All possible combinations of extra V_VT() flags */ static const VARTYPE ExtraFlags[16] = { 0, VT_VECTOR, VT_ARRAY, VT_BYREF, VT_RESERVED, VT_VECTOR|VT_ARRAY, VT_VECTOR|VT_BYREF, VT_VECTOR|VT_RESERVED, VT_VECTOR|VT_ARRAY|VT_BYREF, VT_VECTOR|VT_ARRAY|VT_RESERVED, VT_VECTOR|VT_BYREF|VT_RESERVED, VT_VECTOR|VT_ARRAY|VT_BYREF|VT_RESERVED, VT_ARRAY|VT_BYREF, VT_ARRAY|VT_RESERVED, VT_ARRAY|VT_BYREF|VT_RESERVED, VT_BYREF|VT_RESERVED, }; /* Determine if a vt is valid for VariantClear() */ static int IsValidVariantClearVT(VARTYPE vt, VARTYPE extraFlags) { int ret = 0; /* Only the following flags/types are valid */ if ((vt <= VT_LPWSTR || vt == VT_RECORD || vt == VT_CLSID) && vt != (VARTYPE)15 && (vt < (VARTYPE)24 || vt > (VARTYPE)31) && (!(extraFlags & (VT_BYREF|VT_ARRAY)) || vt > VT_NULL) && (extraFlags == 0 || extraFlags == VT_BYREF || extraFlags == VT_ARRAY || extraFlags == (VT_ARRAY|VT_BYREF))) ret = 1; /* ok */ if ((vt == VT_RECORD && !HAVE_OLEAUT32_RECORD) || ((vt == VT_I8 || vt == VT_UI8) && !HAVE_OLEAUT32_I8)) ret = 0; /* Old versions of oleaut32 */ return ret; } static void test_VariantClear(void) { HRESULT hres; VARIANTARG v; size_t i; #if 0 /* Crashes: Native does not test input for NULL, so neither does Wine */ hres = VariantClear(NULL); #endif /* Only the type field is set, to VT_EMPTY */ V_VT(&v) = VT_UI4; V_UI4(&v) = ~0u; hres = VariantClear(&v); ok((hres == S_OK && V_VT(&v) == VT_EMPTY) || (IS_ANCIENT && hres == DISP_E_BADVARTYPE && V_VT(&v) == VT_UI4), "VariantClear: Type set to %d, res %08lx\n", V_VT(&v), hres); ok(V_UI4(&v) == ~0u, "VariantClear: Overwrote value\n"); /* Test all possible V_VT values. * Also demonstrates that null pointers in 'v' are not dereferenced. * Individual variant tests should test VariantClear() with non-NULL values. */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]) && !IS_ANCIENT; i++) { VARTYPE vt; for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { HRESULT hExpected = DISP_E_BADVARTYPE; SKIPTESTS(vt); memset(&v, 0, sizeof(v)); V_VT(&v) = vt | ExtraFlags[i]; hres = VariantClear(&v); if (IsValidVariantClearVT(vt, ExtraFlags[i])) hExpected = S_OK; ok(hres == hExpected, "VariantClear: expected 0x%lX, got 0x%lX for vt %d | 0x%X\n", hExpected, hres, vt, ExtraFlags[i]); } } } static void test_VariantCopy(void) { VARIANTARG vSrc, vDst; VARTYPE vt; size_t i; HRESULT hres, hExpected; /* Establish that the failure/other cases are dealt with. Individual tests * for each type should verify that data is copied correctly, references * are updated, etc. */ /* vSrc == vDst */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]) && !IS_ANCIENT; i++) { for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { SKIPTESTS(vt); memset(&vSrc, 0, sizeof(vSrc)); V_VT(&vSrc) = vt | ExtraFlags[i]; hExpected = DISP_E_BADVARTYPE; /* src is allowed to be a VT_CLSID */ if (vt != VT_CLSID && IsValidVariantClearVT(vt, ExtraFlags[i])) hExpected = S_OK; hres = VariantCopy(&vSrc, &vSrc); ok(hres == hExpected, "Copy(src==dst): expected 0x%lX, got 0x%lX for src==dest vt %d|0x%X\n", hExpected, hres, vt, ExtraFlags[i]); } } /* Test that if VariantClear() fails on dest, the function fails. This also * shows that dest is in fact cleared and not just overwritten */ memset(&vSrc, 0, sizeof(vSrc)); V_VT(&vSrc) = VT_UI1; for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]) && !IS_ANCIENT; i++) { for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { SKIPTESTS(vt); hExpected = DISP_E_BADVARTYPE; memset(&vDst, 0, sizeof(vDst)); V_VT(&vDst) = vt | ExtraFlags[i]; if (IsValidVariantClearVT(vt, ExtraFlags[i])) hExpected = S_OK; hres = VariantCopy(&vDst, &vSrc); ok(hres == hExpected, "Copy(bad dst): expected 0x%lX, got 0x%lX for dest vt %d|0x%X\n", hExpected, hres, vt, ExtraFlags[i]); if (hres == S_OK) ok(V_VT(&vDst) == VT_UI1, "Copy(bad dst): expected vt = VT_UI1, got %d\n", V_VT(&vDst)); } } /* Test that VariantClear() checks vSrc for validity before copying */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]) && !IS_ANCIENT; i++) { for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { SKIPTESTS(vt); hExpected = DISP_E_BADVARTYPE; memset(&vDst, 0, sizeof(vDst)); V_VT(&vDst) = VT_EMPTY; memset(&vSrc, 0, sizeof(vSrc)); V_VT(&vSrc) = vt | ExtraFlags[i]; /* src is allowed to be a VT_CLSID */ if (vt != VT_CLSID && IsValidVariantClearVT(vt, ExtraFlags[i])) hExpected = S_OK; hres = VariantCopy(&vDst, &vSrc); ok(hres == hExpected, "Copy(bad src): expected 0x%lX, got 0x%lX for src vt %d|0x%X\n", hExpected, hres, vt, ExtraFlags[i]); if (hres == S_OK) ok(V_VT(&vDst) == (vt|ExtraFlags[i]), "Copy(bad src): expected vt = %d, got %d\n", vt | ExtraFlags[i], V_VT(&vDst)); } } } /* Determine if a vt is valid for VariantCopyInd() */ static int IsValidVariantCopyIndVT(VARTYPE vt, VARTYPE extraFlags) { int ret = 0; if ((extraFlags & VT_ARRAY) || (vt > VT_NULL && vt != (VARTYPE)15 && vt < VT_VOID && !(extraFlags & (VT_VECTOR|VT_RESERVED)))) { ret = 1; /* ok */ } return ret; } static void test_VariantCopyInd(void) { VARIANTARG vSrc, vDst, vRef, vRef2; VARTYPE vt; size_t i; BYTE buffer[64]; HRESULT hres, hExpected; memset(buffer, 0, sizeof(buffer)); /* vSrc == vDst */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]) && !IS_ANCIENT; i++) { if (ExtraFlags[i] & VT_ARRAY) continue; /* Native crashes on NULL safearray */ for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { SKIPTESTS(vt); memset(&vSrc, 0, sizeof(vSrc)); V_VT(&vSrc) = vt | ExtraFlags[i]; hExpected = DISP_E_BADVARTYPE; if (!(ExtraFlags[i] & VT_BYREF)) { /* if src is not by-reference, acts as VariantCopy() */ if (vt != VT_CLSID && IsValidVariantClearVT(vt, ExtraFlags[i])) hExpected = S_OK; } else { if (vt == VT_SAFEARRAY || vt == VT_BSTR || vt == VT_UNKNOWN || vt == VT_DISPATCH || vt == VT_RECORD) continue; /* Need valid ptrs for deep copies */ V_BYREF(&vSrc) = &buffer; hExpected = E_INVALIDARG; if ((vt == VT_I8 || vt == VT_UI8) && ExtraFlags[i] == VT_BYREF) { if (HAVE_OLEAUT32_I8) hExpected = S_OK; /* Only valid if I8 is a known type */ } else if (IsValidVariantCopyIndVT(vt, ExtraFlags[i])) hExpected = S_OK; } hres = VariantCopyInd(&vSrc, &vSrc); ok(hres == hExpected, "CopyInd(src==dst): expected 0x%lX, got 0x%lX for src==dst vt %d|0x%X\n", hExpected, hres, vt, ExtraFlags[i]); } } /* Bad dest */ memset(&vSrc, 0, sizeof(vSrc)); V_VT(&vSrc) = VT_UI1|VT_BYREF; V_BYREF(&vSrc) = &buffer; for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]) && !IS_ANCIENT; i++) { for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { SKIPTESTS(vt); memset(&vDst, 0, sizeof(vDst)); V_VT(&vDst) = vt | ExtraFlags[i]; hExpected = DISP_E_BADVARTYPE; if (IsValidVariantClearVT(vt, ExtraFlags[i])) hExpected = S_OK; hres = VariantCopyInd(&vDst, &vSrc); ok(hres == hExpected, "CopyInd(bad dst): expected 0x%lX, got 0x%lX for dst vt %d|0x%X\n", hExpected, hres, vt, ExtraFlags[i]); if (hres == S_OK) ok(V_VT(&vDst) == VT_UI1, "CopyInd(bad dst): expected vt = VT_UI1, got %d\n", V_VT(&vDst)); } } /* bad src */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]) && !IS_ANCIENT; i++) { if (ExtraFlags[i] & VT_ARRAY) continue; /* Native crashes on NULL safearray */ for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { SKIPTESTS(vt); memset(&vDst, 0, sizeof(vDst)); V_VT(&vDst) = VT_EMPTY; memset(&vSrc, 0, sizeof(vSrc)); V_VT(&vSrc) = vt | ExtraFlags[i]; hExpected = DISP_E_BADVARTYPE; if (!(ExtraFlags[i] & VT_BYREF)) { /* if src is not by-reference, acts as VariantCopy() */ if (vt != VT_CLSID && IsValidVariantClearVT(vt, ExtraFlags[i])) hExpected = S_OK; } else { if (vt == VT_SAFEARRAY || vt == VT_BSTR || vt == VT_UNKNOWN || vt == VT_DISPATCH || vt == VT_RECORD) continue; /* Need valid ptrs for deep copies, see vartype.c */ V_BYREF(&vSrc) = &buffer; hExpected = E_INVALIDARG; if ((vt == VT_I8 || vt == VT_UI8) && ExtraFlags[i] == VT_BYREF) { if (HAVE_OLEAUT32_I8) hExpected = S_OK; /* Only valid if I8 is a known type */ } else if (IsValidVariantCopyIndVT(vt, ExtraFlags[i])) hExpected = S_OK; } hres = VariantCopyInd(&vDst, &vSrc); ok(hres == hExpected, "CopyInd(bad src): expected 0x%lX, got 0x%lX for src vt %d|0x%X\n", hExpected, hres, vt, ExtraFlags[i]); if (hres == S_OK) { if (vt == VT_VARIANT && ExtraFlags[i] == VT_BYREF) { /* Type of vDst should be the type of the referenced variant. * Since we set the buffer to all zeros, its type should be * VT_EMPTY. */ ok(V_VT(&vDst) == VT_EMPTY, "CopyInd(bad src): expected dst vt = VT_EMPTY, got %d|0x%X\n", V_VT(&vDst) & VT_TYPEMASK, V_VT(&vDst) & ~VT_TYPEMASK); } else { ok(V_VT(&vDst) == (vt|(ExtraFlags[i] & ~VT_BYREF)), "CopyInd(bad src): expected dst vt = %d|0x%X, got %d|0x%X\n", vt, ExtraFlags[i] & ~VT_BYREF, V_VT(&vDst) & VT_TYPEMASK, V_VT(&vDst) & ~VT_TYPEMASK); } } } } /* By-reference variants are dereferenced */ V_VT(&vRef) = VT_UI1; V_UI1(&vRef) = 0x77; V_VT(&vSrc) = VT_VARIANT|VT_BYREF; V_VARIANTREF(&vSrc) = &vRef; VariantInit(&vDst); hres = VariantCopyInd(&vDst, &vSrc); ok(V_VT(&vDst) == VT_UI1 && V_UI1(&vDst) == 0x77, "CopyInd(deref): expected dst vt = VT_UI1, val 0x77, got %d|0x%X, 0x%2X\n", V_VT(&vDst) & VT_TYPEMASK, V_VT(&vDst) & ~VT_TYPEMASK, V_UI1(&vDst)); /* By-reference variant to a by-reference type succeeds */ V_VT(&vRef) = VT_UI1|VT_BYREF; V_UI1REF(&vRef) = buffer; buffer[0] = 0x88; V_VT(&vSrc) = VT_VARIANT|VT_BYREF; V_VARIANTREF(&vSrc) = &vRef; VariantInit(&vDst); hres = VariantCopyInd(&vDst, &vSrc); ok(V_VT(&vDst) == VT_UI1 && V_UI1(&vDst) == 0x88, "CopyInd(deref): expected dst vt = VT_UI1, val 0x77, got %d|0x%X, 0x%2X\n", V_VT(&vDst) & VT_TYPEMASK, V_VT(&vDst) & ~VT_TYPEMASK, V_UI1(&vDst)); /* But a by-reference variant to a by-reference variant fails */ V_VT(&vRef2) = VT_UI1; V_UI1(&vRef2) = 0x77; V_VT(&vRef) = VT_VARIANT|VT_BYREF; V_VARIANTREF(&vRef) = &vRef2; V_VT(&vSrc) = VT_VARIANT|VT_BYREF; V_VARIANTREF(&vSrc) = &vRef; VariantInit(&vDst); hres = VariantCopyInd(&vDst, &vSrc); ok(hres == E_INVALIDARG, "CopyInd(ref->ref): expected E_INVALIDARG, got 0x%08lx\n", hres); } static HRESULT (WINAPI *pVarParseNumFromStr)(OLECHAR*,LCID,ULONG,NUMPARSE*,BYTE*); /* Macros for converting and testing the result of VarParseNumFromStr */ #define FAILDIG 255 #define CONVERTN(str,dig,flags) MultiByteToWideChar(CP_ACP,0,str,-1,buff,sizeof(buff)); \ memset(rgb, FAILDIG, sizeof(rgb)); memset(&np,-1,sizeof(np)); np.cDig = dig; np.dwInFlags = flags; \ hres = pVarParseNumFromStr(buff,lcid,LOCALE_NOUSEROVERRIDE,&np,rgb) #define CONVERT(str,flags) CONVERTN(str,sizeof(rgb),flags) #define EXPECT(a,b,c,d,e,f) ok(hres == (HRESULT)S_OK, "Call failed, hres = %08lx\n", hres); \ if (hres == (HRESULT)S_OK) { \ ok(np.cDig == (a), "Expected cDig = %d, got %d\n", (a), np.cDig); \ ok(np.dwInFlags == (b), "Expected dwInFlags = 0x%lx, got 0x%lx\n", (ULONG)(b), np.dwInFlags); \ ok(np.dwOutFlags == (c), "Expected dwOutFlags = 0x%lx, got 0x%lx\n", (ULONG)(c), np.dwOutFlags); \ ok(np.cchUsed == (d), "Expected cchUsed = %d, got %d\n", (d), np.cchUsed); \ ok(np.nBaseShift == (e), "Expected nBaseShift = %d, got %d\n", (e), np.nBaseShift); \ ok(np.nPwr10 == (f), "Expected nPwr10 = %d, got %d\n", (f), np.nPwr10); \ } #define EXPECTRGB(a,b) ok(rgb[a] == b, "Digit[%d], expected %d, got %d\n", a, b, rgb[a]) #define EXPECTFAIL ok(hres == (HRESULT)DISP_E_TYPEMISMATCH, "Call succeeded, hres = %08lx\n", hres) #define EXPECT2(a,b) EXPECTRGB(0,a); EXPECTRGB(1,b) static void test_VarParseNumFromStr(void) { HRESULT hres; OLECHAR buff[128]; /* Ensure all tests are using the same locale characters for '$', ',' etc */ LCID lcid = MAKELCID(MAKELANGID(LANG_ENGLISH,SUBLANG_ENGLISH_US),SORT_DEFAULT); NUMPARSE np; BYTE rgb[128]; /** No flags **/ CHECKPTR(VarParseNumFromStr); /* Consume a single digit */ CONVERT("7", 0); EXPECT(1,0,0,1,0,0); EXPECT2(7,FAILDIG); /* cDig is not literal digits - zeros are suppressed and nPwr10 is increased */ CONVERT("10", 0); EXPECT(1,0,0,2,0,1); /* Note: Win32 writes the trailing zeros if they are within cDig's limits, * but then excludes them from the returned cDig count. * In our implementation we don't bother writing them at all. */ EXPECTRGB(0, 1); /* if cDig is too small and numbers follow, sets INEXACT */ CONVERTN("11",1, 0); EXPECT(1,0,NUMPRS_INEXACT,2,0,1); EXPECT2(1,FAILDIG); /* Strips leading zeros */ CONVERT("01", 0); EXPECT(1,0,0,2,0,0); EXPECT2(1,FAILDIG); /* Strips leading zeros */ CONVERTN("01",1, 0); EXPECT(1,0,0,2,0,0); EXPECT2(1,FAILDIG); /* Fails on non digits */ CONVERT("a", 0); EXPECTFAIL; EXPECTRGB(0,FAILDIG); /** NUMPRS_LEADING_WHITE/NUMPRS_TRAILING_WHITE **/ /* Without flag, fails on whitespace */ CONVERT(" 0", 0); EXPECTFAIL; EXPECTRGB(0,FAILDIG); /* With flag, consumes whitespace */ CONVERT(" 0", NUMPRS_LEADING_WHITE); EXPECT(1,NUMPRS_LEADING_WHITE,NUMPRS_LEADING_WHITE,2,0,0); EXPECT2(0,FAILDIG); /* Test TAB once, then assume it acts as space for all cases */ CONVERT("\t0", NUMPRS_LEADING_WHITE); EXPECT(1,NUMPRS_LEADING_WHITE,NUMPRS_LEADING_WHITE,2,0,0); EXPECT2(0,FAILDIG); /* Doesn't pick up trailing whitespace without flag */ CONVERT("0 ", 0); EXPECT(1,0,0,1,0,0); EXPECT2(0,FAILDIG); /* With flag, consumes trailing whitespace */ CONVERT("0 ", NUMPRS_TRAILING_WHITE); EXPECT(1,NUMPRS_TRAILING_WHITE,NUMPRS_TRAILING_WHITE,2,0,0); EXPECT2(0,FAILDIG); /* Leading flag only consumes leading */ CONVERT(" 0 ", NUMPRS_LEADING_WHITE); EXPECT(1,NUMPRS_LEADING_WHITE,NUMPRS_LEADING_WHITE,2,0,0); EXPECT2(0,FAILDIG); /* Both flags consumes both */ CONVERT(" 0 ", NUMPRS_LEADING_WHITE|NUMPRS_TRAILING_WHITE); EXPECT(1,NUMPRS_LEADING_WHITE|NUMPRS_TRAILING_WHITE,NUMPRS_LEADING_WHITE|NUMPRS_TRAILING_WHITE,3,0,0); EXPECT2(0,FAILDIG); /** NUMPRS_LEADING_PLUS/NUMPRS_TRAILING_PLUS **/ /* Without flag, fails on + */ CONVERT("+0", 0); EXPECTFAIL; EXPECTRGB(0,FAILDIG); /* With flag, consumes + */ CONVERT("+0", NUMPRS_LEADING_PLUS); EXPECT(1,NUMPRS_LEADING_PLUS,NUMPRS_LEADING_PLUS,2,0,0); EXPECT2(0,FAILDIG); /* Without flag, doesn't consume trailing + */ CONVERT("0+", 0); EXPECT(1,0,0,1,0,0); EXPECT2(0,FAILDIG); /* With flag, consumes trailing + */ CONVERT("0+", NUMPRS_TRAILING_PLUS); EXPECT(1,NUMPRS_TRAILING_PLUS,NUMPRS_TRAILING_PLUS,2,0,0); EXPECT2(0,FAILDIG); /* With leading flag, doesn't consume trailing + */ CONVERT("+0+", NUMPRS_LEADING_PLUS); EXPECT(1,NUMPRS_LEADING_PLUS,NUMPRS_LEADING_PLUS,2,0,0); EXPECT2(0,FAILDIG); /* Trailing + doesn't get consumed if we specify both (unlike whitespace) */ CONVERT("+0+", NUMPRS_LEADING_PLUS|NUMPRS_TRAILING_PLUS); EXPECT(1,NUMPRS_LEADING_PLUS|NUMPRS_TRAILING_PLUS,NUMPRS_LEADING_PLUS,2,0,0); EXPECT2(0,FAILDIG); /** NUMPRS_LEADING_MINUS/NUMPRS_TRAILING_MINUS **/ /* Without flag, fails on - */ CONVERT("-0", 0); EXPECTFAIL; EXPECTRGB(0,FAILDIG); /* With flag, consumes - */ CONVERT("-0", NUMPRS_LEADING_MINUS); EXPECT(1,NUMPRS_LEADING_MINUS,NUMPRS_NEG|NUMPRS_LEADING_MINUS,2,0,0); EXPECT2(0,FAILDIG); /* Without flag, doesn't consume trailing - */ CONVERT("0-", 0); EXPECT(1,0,0,1,0,0); EXPECT2(0,FAILDIG); /* With flag, consumes trailing - */ CONVERT("0-", NUMPRS_TRAILING_MINUS); EXPECT(1,NUMPRS_TRAILING_MINUS,NUMPRS_NEG|NUMPRS_TRAILING_MINUS,2,0,0); EXPECT2(0,FAILDIG); /* With leading flag, doesn't consume trailing - */ CONVERT("-0-", NUMPRS_LEADING_MINUS); EXPECT(1,NUMPRS_LEADING_MINUS,NUMPRS_NEG|NUMPRS_LEADING_MINUS,2,0,0); EXPECT2(0,FAILDIG); /* Trailing - doesn't get consumed if we specify both (unlike whitespace) */ CONVERT("-0-", NUMPRS_LEADING_MINUS|NUMPRS_TRAILING_MINUS); EXPECT(1,NUMPRS_LEADING_MINUS|NUMPRS_TRAILING_MINUS,NUMPRS_NEG|NUMPRS_LEADING_MINUS,2,0,0); EXPECT2(0,FAILDIG); /** NUMPRS_HEX_OCT **/ /* Could be hex, octal or decimal - With flag reads as decimal */ CONVERT("0", NUMPRS_HEX_OCT); EXPECT(1,NUMPRS_HEX_OCT,0,1,0,0); EXPECT2(0,FAILDIG); /* Doesn't recognise hex in .asm sytax */ CONVERT("0h", NUMPRS_HEX_OCT); EXPECT(1,NUMPRS_HEX_OCT,0,1,0,0); EXPECT2(0,FAILDIG); /* Doesn't fail with valid leading string but no digits */ CONVERT("0x", NUMPRS_HEX_OCT); EXPECT(1,NUMPRS_HEX_OCT,0,1,0,0); EXPECT2(0,FAILDIG); /* Doesn't recognise hex format humbers at all! */ CONVERT("0x0", NUMPRS_HEX_OCT); EXPECT(1,NUMPRS_HEX_OCT,0,1,0,0); EXPECT2(0,FAILDIG); /* Doesn't recognise plain hex digits either */ CONVERT("FE", NUMPRS_HEX_OCT); EXPECTFAIL; EXPECTRGB(0,FAILDIG); /* Octal */ CONVERT("0100", NUMPRS_HEX_OCT); EXPECT(1,NUMPRS_HEX_OCT,0,4,0,2); EXPECTRGB(0,1); EXPECTRGB(1,0); EXPECTRGB(2,0); EXPECTRGB(3,FAILDIG); /* VB hex */ CONVERT("&HF800", NUMPRS_HEX_OCT); EXPECT(4,NUMPRS_HEX_OCT,0x40,6,4,0); EXPECTRGB(0,15); EXPECTRGB(1,8); EXPECTRGB(2,0); EXPECTRGB(3,0); EXPECTRGB(4,FAILDIG); /* VB hex lower case and leading zero */ CONVERT("&h0abcd", NUMPRS_HEX_OCT); EXPECT(4,NUMPRS_HEX_OCT,0x40,7,4,0); EXPECTRGB(0,10); EXPECTRGB(1,11); EXPECTRGB(2,12); EXPECTRGB(3,13); EXPECTRGB(4,FAILDIG); /* VB oct */ CONVERT("&O300", NUMPRS_HEX_OCT); EXPECT(3,NUMPRS_HEX_OCT,0x40,5,3,0); EXPECTRGB(0,3); EXPECTRGB(1,0); EXPECTRGB(2,0); EXPECTRGB(3,FAILDIG); /* VB oct lower case and leading zero */ CONVERT("&o0777", NUMPRS_HEX_OCT); EXPECT(3,NUMPRS_HEX_OCT,0x40,6,3,0); EXPECTRGB(0,7); EXPECTRGB(1,7); EXPECTRGB(2,7); EXPECTRGB(3,FAILDIG); /* VB oct char bigger than 7 */ CONVERT("&o128", NUMPRS_HEX_OCT); /* Native versions 2.x of oleaut32 allow this to succeed: later versions and Wine don't EXPECTFAIL; EXPECTRGB(0,FAILDIG); */ /** NUMPRS_PARENS **/ /* Empty parens = error */ CONVERT("()", NUMPRS_PARENS); EXPECTFAIL; EXPECTRGB(0,FAILDIG); /* With flag, trailing parens not consumed */ CONVERT("0()", NUMPRS_PARENS); EXPECT(1,NUMPRS_PARENS,0,1,0,0); EXPECT2(0,FAILDIG); /* With flag, Number in parens made negative and parens consumed */ CONVERT("(0)", NUMPRS_PARENS); EXPECT(1,NUMPRS_PARENS,NUMPRS_NEG|NUMPRS_PARENS,3,0,0); EXPECT2(0,FAILDIG); /** NUMPRS_THOUSANDS **/ /* With flag, thousands sep. not needed */ CONVERT("0", NUMPRS_THOUSANDS); EXPECT(1,NUMPRS_THOUSANDS,0,1,0,0); EXPECT2(0,FAILDIG); /* With flag, thousands sep. and following digits consumed */ CONVERT("1,000", NUMPRS_THOUSANDS); EXPECT(1,NUMPRS_THOUSANDS,NUMPRS_THOUSANDS,5,0,3); EXPECTRGB(0,1); /* With flag and decimal point, thousands sep. but not decimals consumed */ CONVERT("1,000.0", NUMPRS_THOUSANDS); EXPECT(1,NUMPRS_THOUSANDS,NUMPRS_THOUSANDS,5,0,3); EXPECTRGB(0,1); /** NUMPRS_CURRENCY **/ /* Without flag, chokes on currency sign */ CONVERT("$11", 0); EXPECTFAIL; EXPECTRGB(0,FAILDIG); /* With flag, consumes currency sign */ CONVERT("$11", NUMPRS_CURRENCY); EXPECT(2,NUMPRS_CURRENCY,NUMPRS_CURRENCY,3,0,0); EXPECT2(1,1); EXPECTRGB(2,FAILDIG); /* With flag only, doesn't consume decimal point */ CONVERT("$11.1", NUMPRS_CURRENCY); EXPECT(2,NUMPRS_CURRENCY,NUMPRS_CURRENCY,3,0,0); EXPECT2(1,1); EXPECTRGB(2,FAILDIG); /* With flag and decimal flag, consumes decimal point and following digits */ CONVERT("$11.1", NUMPRS_CURRENCY|NUMPRS_DECIMAL); EXPECT(3,NUMPRS_CURRENCY|NUMPRS_DECIMAL,NUMPRS_CURRENCY|NUMPRS_DECIMAL,5,0,-1); EXPECT2(1,1); EXPECTRGB(2,1); EXPECTRGB(3,FAILDIG); /* Thousands flag can only be used with currency */ CONVERT("$1,234", NUMPRS_CURRENCY|NUMPRS_THOUSANDS); EXPECT(4,NUMPRS_CURRENCY|NUMPRS_THOUSANDS,NUMPRS_CURRENCY|NUMPRS_THOUSANDS,6,0,0); EXPECT2(1,2); EXPECTRGB(2,3); EXPECTRGB(3,4); EXPECTRGB(4,FAILDIG); /** NUMPRS_DECIMAL **/ /* With flag, consumes decimal point */ CONVERT("1.1", NUMPRS_DECIMAL); EXPECT(2,NUMPRS_DECIMAL,NUMPRS_DECIMAL,3,0,-1); EXPECT2(1,1); EXPECTRGB(2,FAILDIG); /* With flag, consumes decimal point. Skipping the decimal part is not an error */ CONVERT("1.", NUMPRS_DECIMAL); EXPECT(1,NUMPRS_DECIMAL,NUMPRS_DECIMAL,2,0,0); EXPECT2(1,FAILDIG); /* Consumes only one decimal point */ CONVERT("1.1.", NUMPRS_DECIMAL); EXPECT(2,NUMPRS_DECIMAL,NUMPRS_DECIMAL,3,0,-1); EXPECT2(1,1); EXPECTRGB(2,FAILDIG); /** NUMPRS_EXPONENT **/ /* Without flag, doesn't consume exponent */ CONVERT("1e1", 0); EXPECT(1,0,0,1,0,0); EXPECT2(1,FAILDIG); /* With flag, consumes exponent */ CONVERT("1e1", NUMPRS_EXPONENT); EXPECT(1,NUMPRS_EXPONENT,NUMPRS_EXPONENT,3,0,1); EXPECT2(1,FAILDIG); /* Negative exponents are accepted without flags */ CONVERT("1e-1", NUMPRS_EXPONENT); EXPECT(1,NUMPRS_EXPONENT,NUMPRS_EXPONENT,4,0,-1); EXPECT2(1,FAILDIG); /* As are positive exponents and leading exponent 0's */ CONVERT("1e+01", NUMPRS_EXPONENT); EXPECT(1,NUMPRS_EXPONENT,NUMPRS_EXPONENT,5,0,1); EXPECT2(1,FAILDIG); /* The same for zero exponents */ CONVERT("1e0", NUMPRS_EXPONENT); EXPECT(1,NUMPRS_EXPONENT,NUMPRS_EXPONENT,3,0,0); EXPECT2(1,FAILDIG); /* Sign on a zero exponent doesn't matter */ CONVERT("1e+0", NUMPRS_EXPONENT); EXPECT(1,NUMPRS_EXPONENT,NUMPRS_EXPONENT,4,0,0); EXPECT2(1,FAILDIG); CONVERT("1e-0", NUMPRS_EXPONENT); EXPECT(1,NUMPRS_EXPONENT,NUMPRS_EXPONENT,4,0,0); EXPECT2(1,FAILDIG); /* Doesn't consume a real number exponent */ CONVERT("1e1.", NUMPRS_EXPONENT); EXPECT(1,NUMPRS_EXPONENT,NUMPRS_EXPONENT,3,0,1); EXPECT2(1,FAILDIG); /* Powers of 10 are calculated from the position of any decimal point */ CONVERT("1.5e20", NUMPRS_EXPONENT|NUMPRS_DECIMAL); EXPECT(2,NUMPRS_EXPONENT|NUMPRS_DECIMAL,NUMPRS_EXPONENT|NUMPRS_DECIMAL,6,0,19); EXPECT2(1,5); CONVERT("1.5e-20", NUMPRS_EXPONENT|NUMPRS_DECIMAL); EXPECT(2,NUMPRS_EXPONENT|NUMPRS_DECIMAL,NUMPRS_EXPONENT|NUMPRS_DECIMAL,7,0,-21); EXPECT2(1,5); /** NUMPRS_USE_ALL **/ /* Flag expects all digits */ CONVERT("0", NUMPRS_USE_ALL); EXPECT(1,NUMPRS_USE_ALL,0,1,0,0); EXPECT2(0,FAILDIG); /* Rejects anything trailing */ CONVERT("0 ", NUMPRS_USE_ALL); EXPECTFAIL; EXPECT2(0,FAILDIG); /* Unless consumed by trailing flag */ CONVERT("0 ", NUMPRS_USE_ALL|NUMPRS_TRAILING_WHITE); EXPECT(1,NUMPRS_USE_ALL|NUMPRS_TRAILING_WHITE,NUMPRS_TRAILING_WHITE,2,0,0); EXPECT2(0,FAILDIG); /** Combinations **/ /* Leading whitepace and plus, doesn't consume trailing whitespace */ CONVERT("+ 0 ", NUMPRS_LEADING_PLUS|NUMPRS_LEADING_WHITE); EXPECT(1,NUMPRS_LEADING_PLUS|NUMPRS_LEADING_WHITE,NUMPRS_LEADING_PLUS|NUMPRS_LEADING_WHITE,3,0,0); EXPECT2(0,FAILDIG); /* Order of whitepace and plus is unimportant */ CONVERT(" +0", NUMPRS_LEADING_PLUS|NUMPRS_LEADING_WHITE); EXPECT(1,NUMPRS_LEADING_PLUS|NUMPRS_LEADING_WHITE,NUMPRS_LEADING_PLUS|NUMPRS_LEADING_WHITE,3,0,0); EXPECT2(0,FAILDIG); /* Leading whitespace can be repeated */ CONVERT(" + 0", NUMPRS_LEADING_PLUS|NUMPRS_LEADING_WHITE); EXPECT(1,NUMPRS_LEADING_PLUS|NUMPRS_LEADING_WHITE,NUMPRS_LEADING_PLUS|NUMPRS_LEADING_WHITE,4,0,0); EXPECT2(0,FAILDIG); /* But plus/minus etc. cannot */ CONVERT("+ +0", NUMPRS_LEADING_PLUS|NUMPRS_LEADING_WHITE); EXPECTFAIL; EXPECTRGB(0,FAILDIG); /* Inexact is not set if trailing zeros are removed */ CONVERTN("10", 1, 0); EXPECT(1,0,0,2,0,1); EXPECT2(1,FAILDIG); /* Make sure a leading 0 is stripped but decimals after it get read */ CONVERT("-0.51", NUMPRS_STD); EXPECT(2,NUMPRS_STD,NUMPRS_NEG|NUMPRS_DECIMAL|NUMPRS_LEADING_MINUS,5,0,-2); EXPECT2(5,1); /* Keep trailing zeros on whole number part of a decimal */ CONVERT("10.1", NUMPRS_STD); EXPECT(3,NUMPRS_STD,NUMPRS_DECIMAL,4,0,-1); EXPECT2(1,0); EXPECTRGB(2,1); /* Zeros after decimal sign */ CONVERT("0.01", NUMPRS_STD); EXPECT(1,NUMPRS_STD,NUMPRS_DECIMAL,4,0,-2); EXPECT2(1,FAILDIG); /* Trailing zeros after decimal part */ CONVERT("0.10", NUMPRS_STD); EXPECT(1,NUMPRS_STD,NUMPRS_DECIMAL,4,0,-1); EXPECT2(1,0); } static HRESULT (WINAPI *pVarNumFromParseNum)(NUMPARSE*,BYTE*,ULONG,VARIANT*); /* Macros for converting and testing the result of VarNumFromParseNum */ #define SETRGB(indx,val) if (!indx) memset(rgb, FAILDIG, sizeof(rgb)); rgb[indx] = val #undef CONVERT #define CONVERT(a,b,c,d,e,f,bits) \ np.cDig = (a); np.dwInFlags = (b); np.dwOutFlags = (c); np.cchUsed = (d); \ np.nBaseShift = (e); np.nPwr10 = (f); hres = pVarNumFromParseNum(&np, rgb, bits, &vOut) static const char *szFailOverflow = "Expected overflow, hres = %08lx\n"; #define EXPECT_OVERFLOW ok(hres == (HRESULT)DISP_E_OVERFLOW, szFailOverflow, hres) static const char *szFailOk = "Call failed, hres = %08lx\n"; #define EXPECT_OK ok(hres == (HRESULT)S_OK, szFailOk, hres); \ if (hres == (HRESULT)S_OK) #define EXPECT_TYPE(typ) ok(V_VT(&vOut) == typ,"Expected Type = " #typ ", got %d\n", V_VT(&vOut)) #define EXPECT_I1(val) EXPECT_OK { EXPECT_TYPE(VT_I1); \ ok(V_I1(&vOut) == val, "Expected i1 = %d, got %d\n", (signed char)val, V_I1(&vOut)); } #define EXPECT_UI1(val) EXPECT_OK { EXPECT_TYPE(VT_UI1); \ ok(V_UI1(&vOut) == val, "Expected ui1 = %d, got %d\n", (BYTE)val, V_UI1(&vOut)); } #define EXPECT_I2(val) EXPECT_OK { EXPECT_TYPE(VT_I2); \ ok(V_I2(&vOut) == val, "Expected i2 = %d, got %d\n", (SHORT)val, V_I2(&vOut)); } #define EXPECT_UI2(val) EXPECT_OK { EXPECT_TYPE(VT_UI2); \ ok(V_UI2(&vOut) == val, "Expected ui2 = %d, got %d\n", (USHORT)val, V_UI2(&vOut)); } #define EXPECT_I4(val) EXPECT_OK { EXPECT_TYPE(VT_I4); \ ok(V_I4(&vOut) == val, "Expected i4 = %ld, got %ld\n", (LONG)val, V_I4(&vOut)); } #define EXPECT_UI4(val) EXPECT_OK { EXPECT_TYPE(VT_UI4); \ ok(V_UI4(&vOut) == val, "Expected ui4 = %ld, got %ld\n", (ULONG)val, V_UI4(&vOut)); } #define EXPECT_I8(high,low) EXPECT_OK { EXPECT_TYPE(VT_I8); \ ok(V_I8(&vOut) == ((((LONG64)(high))<<32)|(low)), "Expected i8 = %lx%08lx, got %lx%08lx\n", \ (LONG)(high), (LONG)(low), (LONG)(V_I8(&vOut)>>32), (LONG)V_I8(&vOut) ); } #define EXPECT_UI8(val) EXPECT_OK { EXPECT_TYPE(VT_UI8); \ ok(V_UI8(&vOut) == val, "Expected ui8 = %lld, got %lld\n", (ULONG64)val, V_UI8(&vOut)); } #define EXPECT_R4(val) EXPECT_OK { EXPECT_TYPE(VT_R4); \ ok(V_R4(&vOut) == val, "Expected r4 = %f, got %f\n", val, V_R4(&vOut)); } #define EXPECT_R8(val) EXPECT_OK { EXPECT_TYPE(VT_R8); \ ok(V_R8(&vOut) == val, "Expected r8 = %g, got %g\n", val, V_R8(&vOut)); } #define CY_MULTIPLIER 10000 #define EXPECT_CY(val) EXPECT_OK { EXPECT_TYPE(VT_CY); \ ok(V_CY(&vOut).int64 == (LONG64)(val * CY_MULTIPLIER), "Expected r8 = %lld, got %lld\n", (LONG64)val, V_CY(&vOut).int64); } static void test_VarNumFromParseNum(void) { HRESULT hres; NUMPARSE np; BYTE rgb[128]; VARIANT vOut; CHECKPTR(VarNumFromParseNum); /* Convert the number 1 to different types */ SETRGB(0, 1); CONVERT(1,0,0,1,0,0, VTBIT_I1); EXPECT_I1(1); SETRGB(0, 1); CONVERT(1,0,0,1,0,0, VTBIT_UI1); EXPECT_UI1(1); /* Prefers a signed type to unsigned of the same size */ SETRGB(0, 1); CONVERT(1,0,0,1,0,0, VTBIT_I1|VTBIT_UI1); EXPECT_I1(1); /* But takes the smaller size if possible */ SETRGB(0, 1); CONVERT(1,0,0,1,0,0, VTBIT_I2|VTBIT_UI1); EXPECT_UI1(1); /* Try different integer sizes */ #define INTEGER_VTBITS (VTBIT_I1|VTBIT_UI1|VTBIT_I2|VTBIT_UI2|VTBIT_I4|VTBIT_UI4|VTBIT_I8|VTBIT_UI8) SETRGB(0, 1); CONVERT(1,0,0,1,0,0, INTEGER_VTBITS); EXPECT_I1(1); /* 127 */ SETRGB(0, 1); SETRGB(1, 2); SETRGB(2, 7); CONVERT(3,0,0,3,0,0, INTEGER_VTBITS); EXPECT_I1(127); /* 128 */ SETRGB(0, 1); SETRGB(1, 2); SETRGB(2, 8); CONVERT(3,0,0,3,0,0, INTEGER_VTBITS); EXPECT_UI1(128); /* 255 */ SETRGB(0, 2); SETRGB(1, 5); SETRGB(2, 5); CONVERT(3,0,0,3,0,0, INTEGER_VTBITS); EXPECT_UI1(255); /* 256 */ SETRGB(0, 2); SETRGB(1, 5); SETRGB(2, 6); CONVERT(3,0,0,3,0,0, INTEGER_VTBITS); EXPECT_I2(256); /* 32767 */ SETRGB(0, 3); SETRGB(1, 2); SETRGB(2, 7); SETRGB(3, 6); SETRGB(4, 7); CONVERT(5,0,0,5,0,0, INTEGER_VTBITS); EXPECT_I2(32767); /* 32768 */ SETRGB(0, 3); SETRGB(1, 2); SETRGB(2, 7); SETRGB(3, 6); SETRGB(4, 8); CONVERT(5,0,0,5,0,0, INTEGER_VTBITS); EXPECT_UI2(32768); /* Assume the above pattern holds for remaining positive integers; test negative */ /* -128 */ SETRGB(0, 1); SETRGB(1, 2); SETRGB(2, 8); CONVERT(3,0,NUMPRS_NEG,3,0,0, INTEGER_VTBITS); EXPECT_I1(-128); /* -129 */ SETRGB(0, 1); SETRGB(1, 2); SETRGB(2, 9); CONVERT(3,0,NUMPRS_NEG,3,0,0, INTEGER_VTBITS); EXPECT_I2(-129); /* -32768 */ SETRGB(0, 3); SETRGB(1, 2); SETRGB(2, 7); SETRGB(3, 6); SETRGB(4, 8); CONVERT(5,0,NUMPRS_NEG,5,0,0, INTEGER_VTBITS); EXPECT_I2(-32768); /* -32768 */ SETRGB(0, 3); SETRGB(1, 2); SETRGB(2, 7); SETRGB(3, 6); SETRGB(4, 9); CONVERT(5,0,NUMPRS_NEG,5,0,0, INTEGER_VTBITS); EXPECT_I4(-32769); /* Assume the above pattern holds for remaining negative integers */ /* Test hexadecimal conversions */ SETRGB(0, 1); CONVERT(1,0,0,1,4,0, INTEGER_VTBITS); EXPECT_I1(0x01); /* 0x7f */ SETRGB(0, 7); SETRGB(1, 0xf); CONVERT(2,0,0,2,4,0, INTEGER_VTBITS); EXPECT_I1(0x7f); /* 0x7fff */ SETRGB(0, 7); SETRGB(1, 0xf); SETRGB(2, 0xf); SETRGB(3, 0xf); CONVERT(4,0,0,4,4,0, INTEGER_VTBITS); EXPECT_I2(0x7fff); /* 0x7fffffff */ SETRGB(0, 7); SETRGB(1, 0xf); SETRGB(2, 0xf); SETRGB(3, 0xf); SETRGB(4, 0xf); SETRGB(5, 0xf); SETRGB(6, 0xf); SETRGB(7, 0xf); CONVERT(8,0,0,8,4,0, INTEGER_VTBITS); EXPECT_I4(0x7fffffffL); /* 0x7fffffffffffffff (64 bits) */ SETRGB(0, 7); SETRGB(1, 0xf); SETRGB(2, 0xf); SETRGB(3, 0xf); SETRGB(4, 0xf); SETRGB(5, 0xf); SETRGB(6, 0xf); SETRGB(7, 0xf); SETRGB(8, 0xf); SETRGB(9, 0xf); SETRGB(10, 0xf); SETRGB(11, 0xf); SETRGB(12, 0xf); SETRGB(13, 0xf); SETRGB(14, 0xf); SETRGB(15, 0xf); if (HAVE_OLEAUT32_I8) { CONVERT(16,0,0,16,4,0, INTEGER_VTBITS); EXPECT_I8(0x7fffffff,0xffffffff); } /* Assume the above pattern holds for numbers without hi-bit set, test (preservation of) hi-bit */ /* 0x82 */ SETRGB(0, 8); SETRGB(1, 2); CONVERT(2,0,0,2,4,0, INTEGER_VTBITS); EXPECT_I1((signed char)0x82); /* 0x8002 */ SETRGB(0, 8); SETRGB(1, 0); SETRGB(2, 0); SETRGB(3, 2); CONVERT(4,0,0,4,4,0, INTEGER_VTBITS); EXPECT_I2((signed short)0x8002); /* 0x80000002 */ SETRGB(0, 8); SETRGB(1, 0); SETRGB(2, 0); SETRGB(3, 0); SETRGB(4, 0); SETRGB(5, 0); SETRGB(6, 0); SETRGB(7, 2); CONVERT(8,0,0,8,4,0, INTEGER_VTBITS); EXPECT_I4(0x80000002L); /* 0x8000000000000002 (64 bits) */ SETRGB(0, 8); SETRGB(1, 0); SETRGB(2, 0); SETRGB(3, 0); SETRGB(4, 0); SETRGB(5, 0); SETRGB(6, 0); SETRGB(7, 0); SETRGB(8, 0); SETRGB(9, 0); SETRGB(10, 0); SETRGB(11, 0); SETRGB(12, 0); SETRGB(13, 0); SETRGB(14, 0); SETRGB(15, 2); if (HAVE_OLEAUT32_I8) { CONVERT(16,0,0,16,4,0, INTEGER_VTBITS); EXPECT_I8(0x80000000,0x00000002); } /* Test (preservation of) hi-bit with STRICT type requesting */ /* 0x82 */ SETRGB(0, 8); SETRGB(1, 2); CONVERT(2,0,0,2,4,0, VTBIT_I1); EXPECT_I1((signed char)0x82); /* 0x8002 */ SETRGB(0, 8); SETRGB(1, 0); SETRGB(2, 0); SETRGB(3, 2); CONVERT(4,0,0,4,4,0, VTBIT_I2); EXPECT_I2((signed short)0x8002); /* 0x80000002 */ SETRGB(0, 8); SETRGB(1, 0); SETRGB(2, 0); SETRGB(3, 0); SETRGB(4, 0); SETRGB(5, 0); SETRGB(6, 0); SETRGB(7, 2); CONVERT(8,0,0,8,4,0, VTBIT_I4); EXPECT_I4(0x80000002L); /* 0x8000000000000002 (64 bits) */ SETRGB(0, 8); SETRGB(1, 0); SETRGB(2, 0); SETRGB(3, 0); SETRGB(4, 0); SETRGB(5, 0); SETRGB(6, 0); SETRGB(7, 0); SETRGB(8, 0); SETRGB(9, 0); SETRGB(10, 0); SETRGB(11, 0); SETRGB(12, 0); SETRGB(13, 0); SETRGB(14, 0); SETRGB(15, 2); if (HAVE_OLEAUT32_I8) { CONVERT(16,0,0,16,4,0, VTBIT_I8); EXPECT_I8(0x80000000,0x00000002); } /* Assume the above pattern holds for numbers with hi-bit set */ /* Negative numbers overflow if we have only unsigned outputs */ /* -1 */ SETRGB(0, 1); CONVERT(1,0,NUMPRS_NEG,1,0,0, VTBIT_UI1); EXPECT_OVERFLOW; /* -0.6 */ SETRGB(0, 6); CONVERT(1,0,NUMPRS_NEG,1,0,~0u, VTBIT_UI1); EXPECT_OVERFLOW; /* Except that rounding is done first, so -0.5 to 0 are accepted as 0 */ /* -0.5 */ SETRGB(0, 5); CONVERT(1,0,NUMPRS_NEG,1,0,~0u, VTBIT_UI1); EXPECT_UI1(0); /* Floating point zero is OK */ /* 0.00000000E0 */ SETRGB(0, 0); CONVERT(1,0,NUMPRS_DECIMAL|NUMPRS_EXPONENT,12,0,-8, VTBIT_R8); EXPECT_R8(0.0); /* Float is acceptable for an integer input value */ SETRGB(0, 1); CONVERT(1,0,0,1,0,0, VTBIT_R4); EXPECT_R4(1.0f); /* As is double */ SETRGB(0, 1); CONVERT(1,0,0,1,0,0, VTBIT_R8); EXPECT_R8(1.0); /* As is currency */ SETRGB(0, 1); CONVERT(1,0,0,1,0,0, VTBIT_CY); EXPECT_CY(1); /* Float is preferred over double */ SETRGB(0, 1); CONVERT(1,0,0,1,0,0, VTBIT_R4|VTBIT_R8); EXPECT_R4(1.0f); /* Double is preferred over currency */ SETRGB(0, 1); CONVERT(1,0,0,1,0,0, VTBIT_R8|VTBIT_CY); EXPECT_R8(1.0); /* Currency is preferred over decimal */ SETRGB(0, 1); CONVERT(1,0,0,1,0,0, VTBIT_CY|VTBIT_DECIMAL); EXPECT_CY(1); } static const char* szUdateFromDateFail = "%.16g expected %lx, %d,%d,%d,%d,%d,%d,%d %d %d" ", got %lx, %d,%d,%d,%d,%d,%d,%d %d %d\n"; #define DT2UD(dt,flags,r,d,m,y,h,mn,s,ms,dw,dy) \ memset(&ud, 0, sizeof(ud)); \ res = pVarUdateFromDate(dt, flags, &ud); \ ok(r == res && (FAILED(r) || (ud.st.wYear == y && ud.st.wMonth == m && ud.st.wDay == d && \ ud.st.wHour == h && ud.st.wMinute == mn && ud.st.wSecond == s && \ ud.st.wMilliseconds == ms && ud.st.wDayOfWeek == dw && ud.wDayOfYear == dy)), \ szUdateFromDateFail, dt, r, d, m, y, h, mn, s, ms, dw, dy, res, ud.st.wDay, ud.st.wMonth, \ ud.st.wYear, ud.st.wHour, ud.st.wMinute, ud.st.wSecond, \ ud.st.wMilliseconds, ud.st.wDayOfWeek, ud.wDayOfYear) static void test_VarUdateFromDate(void) { UDATE ud; HRESULT res; CHECKPTR(VarUdateFromDate); DT2UD(29221.0,0,S_OK,1,1,1980,0,0,0,0,2,1); /* 1 Jan 1980 */ DT2UD(29222.0,0,S_OK,2,1,1980,0,0,0,0,3,2); /* 2 Jan 1980 */ DT2UD(33238.0,0,S_OK,31,12,1990,0,0,0,0,1,365); /* 31 Dec 1990 */ DT2UD(0.0,0,S_OK,30,12,1899,0,0,0,0,6,364); /* 30 Dec 1899 - VT_DATE 0.0 */ DT2UD(-657434.0,0,S_OK,1,1,100,0,0,0,0,5,1); /* 1 Jan 100 - Min */ DT2UD(-657435.0,0,E_INVALIDARG,0,0,0,0,0,0,0,0,0); /* < 1 Jan 100 => err */ DT2UD(2958465.0,0,S_OK,31,12,9999,0,0,0,0,5,365); /* 31 Dec 9999 - Max */ DT2UD(2958466.0,0,E_INVALIDARG,0,0,0,0,0,0,0,0,0); /* > 31 Dec 9999 => err */ /* VAR_VALIDDATE doesn't prevent upper and lower bounds being checked */ DT2UD(-657435.0,VAR_VALIDDATE,E_INVALIDARG,0,0,0,0,0,0,0,0,0); DT2UD(2958466.0,VAR_VALIDDATE,E_INVALIDARG,0,0,0,0,0,0,0,0,0); /* Times */ DT2UD(29221.25,0,S_OK,1,1,1980,6,0,0,0,2,1); /* 6 AM */ DT2UD(29221.33333333,0,S_OK,1,1,1980,8,0,0,0,2,1); /* 8 AM */ DT2UD(29221.5,0,S_OK,1,1,1980,12,0,0,0,2,1); /* 12 AM */ DT2UD(29221.9888884444,0,S_OK,1,1,1980,23,44,0,0,2,1); /* 11:44 PM */ DT2UD(29221.7508765432,0,S_OK,1,1,1980,18,1,16,0,2,1); /* 6:18:02 PM */ } #define UD2T(d,m,y,h,mn,s,ms,dw,dy,flags,r,dt) \ ud.st.wYear = (y); ud.st.wMonth = (m); ud.st.wDay = (d); ud.st.wHour = (h); \ ud.st.wMinute = (mn); ud.st.wSecond = (s); ud.st.wMilliseconds = (ms); \ ud.st.wDayOfWeek = (dw); ud.wDayOfYear = (dy); \ res = pVarDateFromUdate(&ud, (flags), &out); \ ok((r) == res && (FAILED(r) || fabs(out-(dt)) < 1.0e-11), \ "expected %lx, %.16g, got %lx, %.16g\n", r, dt, res, out) static void test_VarDateFromUdate(void) { UDATE ud; double out; HRESULT res; CHECKPTR(VarDateFromUdate); UD2T(1,1,1980,0,0,0,0,2,1,0,S_OK,29221.0); /* 1 Jan 1980 */ UD2T(2,1,1980,0,0,0,0,3,2,0,S_OK,29222.0); /* 2 Jan 1980 */ UD2T(31,12,1990,0,0,0,0,0,0,0,S_OK,33238.0); /* 31 Dec 1990 */ UD2T(31,12,90,0,0,0,0,0,0,0,S_OK,33238.0); /* year < 100 is 1900+year! */ UD2T(30,12,1899,0,0,0,0,6,364,0,S_OK,0.0); /* 30 Dec 1899 - VT_DATE 0.0 */ UD2T(1,1,100,0,0,0,0,0,0,0,S_OK,-657434.0); /* 1 Jan 100 - Min */ UD2T(31,12,9999,0,0,0,0,0,0,0,S_OK,2958465.0); /* 31 Dec 9999 - Max */ UD2T(1,1,10000,0,0,0,0,0,0,0,E_INVALIDARG,0.0); /* > 31 Dec 9999 => err */ UD2T(1,1,1980,18,1,16,0,2,1,0,S_OK,29221.75087962963); /* 6:18:02 PM */ UD2T(0,1,1980,0,0,0,0,2,1,0,S_OK,29220.0); /* Rolls back to 31 Dec 1899 */ UD2T(1,13,1980,0,0,0,0,2,1,0,S_OK,29587.0); /* Rolls fwd to 1/1/1981 */ } #define ST2DT(d,m,y,h,mn,s,ms,r,dt) \ st.wYear = y; st.wMonth = m; st.wDay = d; st.wHour = h; st.wMinute = mn; \ st.wSecond = s; st.wMilliseconds = ms; st.wDayOfWeek = 0; \ res = pSystemTimeToVariantTime(&st, &out); \ ok(r == res && (!r || fabs(out-dt) < 1.0e-11), \ "expected %d, %.16g, got %d, %.16g\n", r, dt, res, out) static void test_SystemTimeToVariantTime(void) { SYSTEMTIME st; double out; int res; CHECKPTR(SystemTimeToVariantTime); ST2DT(1,1,1980,0,0,0,0,TRUE,29221.0); ST2DT(2,1,1980,0,0,0,0,TRUE,29222.0); ST2DT(0,1,1980,0,0,0,0,TRUE,29220.0); /* Rolls back to 31 Dec 1899 */ ST2DT(1,13,1980,0,0,0,0,FALSE,29587.0); /* Fails on invalid month */ ST2DT(31,12,90,0,0,0,0,TRUE,33238.0); /* year < 100 is 1900+year! */ } #define DT2ST(dt,r,d,m,y,h,mn,s,ms) \ memset(&st, 0, sizeof(st)); \ res = pVariantTimeToSystemTime(dt, &st); \ ok(r == res && (!r || (st.wYear == y && st.wMonth == m && st.wDay == d && \ st.wHour == h && st.wMinute == mn && st.wSecond == s && \ st.wMilliseconds == ms)), \ "%.16g expected %d, %d,%d,%d,%d,%d,%d,%d, got %d, %d,%d,%d,%d,%d,%d,%d\n", \ dt, r, d, m, y, h, mn, s, ms, res, st.wDay, st.wMonth, st.wYear, \ st.wHour, st.wMinute, st.wSecond, st.wMilliseconds) static void test_VariantTimeToSystemTime(void) { SYSTEMTIME st; int res; CHECKPTR(VariantTimeToSystemTime); DT2ST(29221.0,1,1,1,1980,0,0,0,0); DT2ST(29222.0,1,2,1,1980,0,0,0,0); } #define MKDOSDATE(d,m,y) ((d & 0x1f) | ((m & 0xf) << 5) | (((y-1980) & 0x7f) << 9)) #define MKDOSTIME(h,m,s) (((s>>1) & 0x1f) | ((m & 0x3f) << 5) | ((h & 0x1f) << 11)) static const char *szDosDateToVarTimeFail = "expected %d, %.16g, got %d, %.16g\n"; #define DOS2DT(d,m,y,h,mn,s,r,dt) out = 0.0; \ dosDate = MKDOSDATE(d,m,y); \ dosTime = MKDOSTIME(h,mn,s); \ res = pDosDateTimeToVariantTime(dosDate, dosTime, &out); \ ok(r == res && (!r || fabs(out-dt) < 1.0e-11), \ szDosDateToVarTimeFail, r, dt, res, out) static void test_DosDateTimeToVariantTime(void) { USHORT dosDate, dosTime; double out; INT res; CHECKPTR(DosDateTimeToVariantTime); /* Date */ DOS2DT(1,1,1980,0,0,0,1,29221.0); /* 1/1/1980 */ DOS2DT(31,12,2099,0,0,0,1,73050.0); /* 31/12/2099 */ /* Dates are limited to the dos date max of 31/12/2099 */ DOS2DT(31,12,2100,0,0,0,0,0.0); /* 31/12/2100 */ /* Days and months of 0 cause date to roll back 1 day or month */ DOS2DT(0,1,1980,0,0,0,1,29220.0); /* 0 Day => 31/12/1979 */ DOS2DT(1,0,1980,0,0,0,1,29190.0); /* 0 Mth => 1/12/1979 */ DOS2DT(0,0,1980,0,0,0,1,29189.0); /* 0 D/M => 30/11/1979 */ /* Days > days in the month cause date to roll forward 1 month */ DOS2DT(29,2,1981,0,0,0,1,29646.0); /* 29/2/1981 -> 3/1/1980 */ DOS2DT(30,2,1981,0,0,0,1,29647.0); /* 30/2/1981 -> 4/1/1980 */ /* Takes leap years into account when rolling forward */ DOS2DT(29,2,1980,0,0,0,1,29280.0); /* 2/29/1980 */ /* Months > 12 cause an error */ DOS2DT(2,13,1980,0,0,0,0,0.0); /* Time */ DOS2DT(1,1,1980,0,0,29,1,29221.00032407407); /* 1/1/1980 12:00:28 AM */ DOS2DT(1,1,1980,0,0,31,1,29221.00034722222); /* 1/1/1980 12:00:30 AM */ DOS2DT(1,1,1980,0,59,0,1,29221.04097222222); /* 1/1/1980 12:59:00 AM */ DOS2DT(1,1,1980,0,60,0,0,0.0); /* Invalid seconds */ DOS2DT(1,1,1980,23,0,0,1,29221.95833333333); /* 1/1/1980 11:00:00 PM */ DOS2DT(1,1,1980,24,0,0,0,0.0); /* Invalid hours */ } #define DT2DOS(dt,r,d,m,y,h,mn,s) dosTime = dosDate = 0; \ expDosDate = MKDOSDATE(d,m,y); \ expDosTime = MKDOSTIME(h,mn,s); \ res = pVariantTimeToDosDateTime(dt, &dosDate, &dosTime); \ ok(r == res && (!r || (dosTime == expDosTime && dosDate == expDosDate)), \ "%g: expected %d,%d(%d/%d/%d),%d(%d:%d:%d) got %d,%d(%d/%d/%d),%d(%d:%d:%d)\n", \ dt, r, expDosDate, expDosDate & 0x1f, (expDosDate >> 5) & 0xf, 1980 + (expDosDate >> 9), \ expDosTime, expDosTime >> 11, (expDosTime >> 5) & 0x3f, (expDosTime & 0x1f), \ res, dosDate, dosDate & 0x1f, (dosDate >> 5) & 0xf, 1980 + (dosDate >> 9), \ dosTime, dosTime >> 11, (dosTime >> 5) & 0x3f, (dosTime & 0x1f)) static void test_VariantTimeToDosDateTime(void) { USHORT dosDate, dosTime, expDosDate, expDosTime; INT res; CHECKPTR(VariantTimeToDosDateTime); /* Date */ DT2DOS(29221.0,1,1,1,1980,0,0,0); /* 1/1/1980 */ DT2DOS(73050.0,1,31,12,2099,0,0,0); /* 31/12/2099 */ DT2DOS(29220.0,0,0,0,0,0,0,0); /* 31/12/1979 - out of range */ DT2DOS(73415.0,0,0,0,0,0,0,0); /* 31/12/2100 - out of range */ /* Time */ DT2DOS(29221.00032407407,1,1,1,1980,0,0,29); /* 1/1/1980 12:00:28 AM */ DT2DOS(29221.00034722222,1,1,1,1980,0,0,31); /* 1/1/1980 12:00:30 AM */ DT2DOS(29221.04097222222,1,1,1,1980,0,59,0); /* 1/1/1980 12:59:00 AM */ DT2DOS(29221.95833333333,1,1,1,1980,23,0,0); /* 1/1/1980 11:00:00 PM */ } #define FMT_NUMBER(vt,val) \ VariantInit(&v); V_VT(&v) = vt; val(&v) = 1; \ hres = pVarFormatNumber(&v,2,0,0,0,0,&str); \ ok(hres == S_OK, "VarFormatNumber (vt %d): returned %8lx\n", vt, hres); \ if (hres == S_OK) \ ok(str && strcmpW(str,szResult1) == 0, \ "VarFormatNumber (vt %d): string different\n", vt) static void test_VarFormatNumber(void) { static const WCHAR szSrc1[] = { '1','\0' }; static const WCHAR szResult1[] = { '1','.','0','0','\0' }; static const WCHAR szSrc2[] = { '-','1','\0' }; static const WCHAR szResult2[] = { '(','1','.','0','0',')','\0' }; char buff[8]; HRESULT hres; VARIANT v; BSTR str = NULL; CHECKPTR(VarFormatNumber); GetLocaleInfoA(LOCALE_USER_DEFAULT, LOCALE_SDECIMAL, buff, sizeof(buff)/sizeof(char)); if (buff[0] != '.' || buff[1]) { trace("Skipping VarFormatNumber tests as decimal separator is '%s'\n", buff); return; } FMT_NUMBER(VT_I1, V_I1); FMT_NUMBER(VT_UI1, V_UI1); FMT_NUMBER(VT_I2, V_I2); FMT_NUMBER(VT_UI2, V_UI2); FMT_NUMBER(VT_I4, V_I4); FMT_NUMBER(VT_UI4, V_UI4); if (HAVE_OLEAUT32_I8) { FMT_NUMBER(VT_I8, V_I8); FMT_NUMBER(VT_UI8, V_UI8); } FMT_NUMBER(VT_R4, V_R4); FMT_NUMBER(VT_R8, V_R8); FMT_NUMBER(VT_BOOL, V_BOOL); V_VT(&v) = VT_BSTR; V_BSTR(&v) = SysAllocString(szSrc1); hres = pVarFormatNumber(&v,2,0,0,0,0,&str); ok(hres == S_OK, "VarFormatNumber (bstr): returned %8lx\n", hres); if (hres == S_OK) ok(str && strcmpW(str, szResult1) == 0, "VarFormatNumber (bstr): string different\n"); SysFreeString(V_BSTR(&v)); SysFreeString(str); V_BSTR(&v) = SysAllocString(szSrc2); hres = pVarFormatNumber(&v,2,0,-1,0,0,&str); ok(hres == S_OK, "VarFormatNumber (bstr): returned %8lx\n", hres); if (hres == S_OK) ok(str && strcmpW(str, szResult2) == 0, "VarFormatNumber (-bstr): string different\n"); SysFreeString(V_BSTR(&v)); SysFreeString(str); } #define SIGNED_VTBITS (VTBIT_I1|VTBIT_I2|VTBIT_I4|VTBIT_I8|VTBIT_R4|VTBIT_R8) static const char *szVarFmtFail = "VT %d|0x%04x Format %s: expected 0x%08lx, '%s', got 0x%08lx, '%s'\n"; #define VARFMT(vt,v,val,fmt,ret,str) do { \ if (out) SysFreeString(out); out = NULL; \ V_VT(&in) = (vt); v(&in) = val; \ if (fmt) MultiByteToWideChar(CP_ACP, 0, fmt, -1, buffW, sizeof(buffW)/sizeof(WCHAR)); \ hres = pVarFormat(&in,fmt ? buffW : NULL,fd,fw,flags,&out); \ if (SUCCEEDED(hres)) WideCharToMultiByte(CP_ACP, 0, out, -1, buff, sizeof(buff),0,0); \ else buff[0] = '\0'; \ ok(hres == ret && (FAILED(ret) || !strcmp(buff, str)), \ szVarFmtFail, \ (vt)&VT_TYPEMASK,(vt)&~VT_TYPEMASK,fmt?fmt:"",ret,str,hres,buff); \ } while(0) typedef struct tagFMTRES { LPCSTR fmt; LPCSTR one_res; LPCSTR zero_res; } FMTRES; static const FMTRES VarFormat_results[] = { { NULL, "1", "0" }, { "", "1", "0" }, { "General Number", "1", "0" }, { "Percent", "100.00%", "0.00%" }, { "Standard", "1.00", "0.00" }, { "Scientific","1.00E+00", "0.00E+00" }, { "True/False", "True", "False" }, { "On/Off", "On", "Off" }, { "Yes/No", "Yes", "No" }, { "#", "1", "" }, { "##", "1", "" }, { "#.#", "1.", "." }, { "0", "1", "0" }, { "00", "01", "00" }, { "0.0", "1.0", "0.0" }, { "00\\c\\o\\p\\y", "01copy","00copy" }, { "\"pos\";\"neg\"", "pos", "pos" }, { "\"pos\";\"neg\";\"zero\"","pos", "zero" } }; typedef struct tagFMTDATERES { DATE val; LPCSTR fmt; LPCSTR res; } FMTDATERES; static const FMTDATERES VarFormat_date_results[] = { { 0.0, "w", "7" }, { 0.0, "w", "6" }, { 0.0, "w", "5" }, { 0.0, "w", "4" }, { 0.0, "w", "3" }, { 0.0, "w", "2" }, { 0.0, "w", "1" }, /* First 7 entries must remain in this order! */ { 2.525, "am/pm", "pm" }, { 2.525, "AM/PM", "PM" }, { 2.525, "A/P", "P" }, { 2.525, "a/p", "p" }, { 2.525, "q", "1" }, { 2.525, "d", "1" }, { 2.525, "dd", "01" }, { 2.525, "ddd", "Mon" }, { 2.525, "dddd", "Monday" }, { 2.525, "mmm", "Jan" }, { 2.525, "mmmm", "January" }, { 2.525, "y", "1" }, { 2.525, "yy", "00" }, { 2.525, "yyy", "001" }, { 2.525, "yyyy", "1900" }, { 2.525, "dd mm yyyy hh:mm:ss", "01 01 1900 12:36:00" }, { 2.525, "dd mm yyyy mm", "01 01 1900 01" }, { 2.525, "dd mm yyyy :mm", "01 01 1900 :01" }, { 2.525, "dd mm yyyy hh:mm", "01 01 1900 12:36" }, { 2.525, "mm mm", "01 01" }, { 2.525, "mm :mm:ss", "01 :01:00" }, { 2.525, "mm :ss:mm", "01 :00:01" }, { 2.525, "hh:mm :ss:mm", "12:36 :00:01" }, { 2.525, "hh:dd :mm:mm", "12:01 :01:01" }, { 2.525, "dd:hh :mm:mm", "01:12 :36:01" }, { 2.525, "hh :mm:mm", "12 :36:01" }, { 2.525, "dd :mm:mm", "01 :01:01" }, { 2.525, "dd :mm:nn", "01 :01:36" }, { 2.725, "hh:nn:ss A/P", "05:24:00 P" } }; #define VNUMFMT(vt,v) \ for (i = 0; i < sizeof(VarFormat_results)/sizeof(FMTRES); i++) \ { \ VARFMT(vt,v,1,VarFormat_results[i].fmt,S_OK,VarFormat_results[i].one_res); \ VARFMT(vt,v,0,VarFormat_results[i].fmt,S_OK,VarFormat_results[i].zero_res); \ } \ if ((1 << vt) & SIGNED_VTBITS) \ { \ VARFMT(vt,v,-1,"\"pos\";\"neg\"",S_OK,"neg"); \ VARFMT(vt,v,-1,"\"pos\";\"neg\";\"zero\"",S_OK,"neg"); \ } static void test_VarFormat(void) { static const WCHAR szTesting[] = { 't','e','s','t','i','n','g','\0' }; size_t i; WCHAR buffW[256]; char buff[256]; VARIANT in; VARIANT_BOOL bTrue = VARIANT_TRUE, bFalse = VARIANT_FALSE; int fd = 0, fw = 0; ULONG flags = 0; BSTR bstrin, out = NULL; HRESULT hres; CHECKPTR(VarFormat); if (PRIMARYLANGID(LANGIDFROMLCID(GetUserDefaultLCID())) != LANG_ENGLISH) { trace("Skipping VarFormat tests for non english language\n"); return; } GetLocaleInfoA(LOCALE_USER_DEFAULT, LOCALE_SDECIMAL, buff, sizeof(buff)/sizeof(char)); if (buff[0] != '.' || buff[1]) { trace("Skipping VarFormat tests as decimal separator is '%s'\n", buff); return; } GetLocaleInfoA(LOCALE_USER_DEFAULT, LOCALE_IDIGITS, buff, sizeof(buff)/sizeof(char)); if (buff[0] != '2' || buff[1]) { trace("Skipping VarFormat tests as decimal places is '%s'\n", buff); return; } VARFMT(VT_BOOL,V_BOOL,VARIANT_TRUE,"True/False",S_OK,"True"); VARFMT(VT_BOOL,V_BOOL,VARIANT_FALSE,"True/False",S_OK,"False"); VNUMFMT(VT_I1,V_I1); VNUMFMT(VT_I2,V_I2); VNUMFMT(VT_I4,V_I4); if (HAVE_OLEAUT32_I8) { VNUMFMT(VT_I8,V_I8); } VNUMFMT(VT_INT,V_INT); VNUMFMT(VT_UI1,V_UI1); VNUMFMT(VT_UI2,V_UI2); VNUMFMT(VT_UI4,V_UI4); if (HAVE_OLEAUT32_I8) { VNUMFMT(VT_UI8,V_UI8); } VNUMFMT(VT_UINT,V_UINT); VNUMFMT(VT_R4,V_R4); VNUMFMT(VT_R8,V_R8); /* Reference types are dereferenced */ VARFMT(VT_BOOL|VT_BYREF,V_BOOLREF,&bTrue,"True/False",S_OK,"True"); VARFMT(VT_BOOL|VT_BYREF,V_BOOLREF,&bFalse,"True/False",S_OK,"False"); /* Dates */ for (i = 0; i < sizeof(VarFormat_date_results)/sizeof(FMTDATERES); i++) { if (i < 7) fd = i + 1; /* Test first day */ else fd = 0; VARFMT(VT_DATE,V_DATE,VarFormat_date_results[i].val, VarFormat_date_results[i].fmt,S_OK, VarFormat_date_results[i].res); } /* Strings */ bstrin = SysAllocString(szTesting); VARFMT(VT_BSTR,V_BSTR,bstrin,"",S_OK,"testing"); VARFMT(VT_BSTR,V_BSTR,bstrin,"@",S_OK,"testing"); VARFMT(VT_BSTR,V_BSTR,bstrin,"&",S_OK,"testing"); VARFMT(VT_BSTR,V_BSTR,bstrin,"\\x@\\x@",S_OK,"xtxesting"); VARFMT(VT_BSTR,V_BSTR,bstrin,"\\x&\\x&",S_OK,"xtxesting"); VARFMT(VT_BSTR,V_BSTR,bstrin,"@\\x",S_OK,"txesting"); VARFMT(VT_BSTR,V_BSTR,bstrin,"@@@@@@@@",S_OK," testing"); VARFMT(VT_BSTR,V_BSTR,bstrin,"@\\x@@@@@@@",S_OK," xtesting"); VARFMT(VT_BSTR,V_BSTR,bstrin,"&&&&&&&&",S_OK,"testing"); VARFMT(VT_BSTR,V_BSTR,bstrin,"!&&&&&&&",S_OK,"testing"); VARFMT(VT_BSTR,V_BSTR,bstrin,"&&&&&&&!",S_OK,"testing"); VARFMT(VT_BSTR,V_BSTR,bstrin,">&&",S_OK,"TESTING"); VARFMT(VT_BSTR,V_BSTR,bstrin,"<&&",S_OK,"testing"); VARFMT(VT_BSTR,V_BSTR,bstrin,"<&>&",S_OK,"testing"); SysFreeString(bstrin); /* Numeric values are converted to strings then output */ VARFMT(VT_I1,V_I1,1,"<&>&",S_OK,"1"); /* Number formats */ VARFMT(VT_I4,V_I4,1,"#00000000",S_OK,"00000001"); VARFMT(VT_I4,V_I4,1,"000###",S_OK,"000001"); VARFMT(VT_I4,V_I4,1,"#00##00#0",S_OK,"00000001"); VARFMT(VT_I4,V_I4,1,"1#####0000",S_OK,"10001"); VARFMT(VT_I4,V_I4,17,"#0",S_OK,"17"); VARFMT(VT_I4,V_I4,4711,"#0",S_OK,"4711"); VARFMT(VT_I4,V_I4,17,"#00",S_OK,"17"); VARFMT(VT_I4,V_I4,17,"#000",S_OK,"017"); VARFMT(VT_I4,V_I4,17,"#0.00",S_OK,"17.00"); VARFMT(VT_I4,V_I4,17,"#0000.00",S_OK,"0017.00"); VARFMT(VT_I4,V_I4,17,"#.00",S_OK,"17.00"); VARFMT(VT_R8,V_R8,1.7,"#.00",S_OK,"1.70"); VARFMT(VT_R8,V_R8,.17,"#.00",S_OK,".17"); VARFMT(VT_I4,V_I4,17,"#3",S_OK,"173"); VARFMT(VT_I4,V_I4,17,"#33",S_OK,"1733"); VARFMT(VT_I4,V_I4,17,"#3.33",S_OK,"173.33"); VARFMT(VT_I4,V_I4,17,"#3333.33",S_OK,"173333.33"); VARFMT(VT_I4,V_I4,17,"#.33",S_OK,"17.33"); VARFMT(VT_R8,V_R8,.17,"#.33",S_OK,".33"); VARFMT(VT_R8,V_R8,1.7,"0.0000E-000",S_OK,"1.7000E000"); VARFMT(VT_R8,V_R8,1.7,"0.0000e-1",S_OK,"1.7000e01"); VARFMT(VT_R8,V_R8,86.936849,"#0.000000000000e-000",S_OK,"86.936849000000e000"); todo_wine { /* rounding */ VARFMT(VT_R8,V_R8,1.7,"#0",S_OK,"2"); VARFMT(VT_R8,V_R8,1.7,"#.33",S_OK,"2.33"); VARFMT(VT_R8,V_R8,1.7,"#3",S_OK,"23"); VARFMT(VT_R8,V_R8,1.73245,"0.0000E+000",S_OK,"1.7325E+000"); VARFMT(VT_R8,V_R8,9.9999999,"#0.000000",S_OK,"10.000000"); /* handling of numbers > 0 with exponent format */ VARFMT(VT_R8,V_R8,1.7,"0.0000e+0#",S_OK,"1.7000e+0"); VARFMT(VT_R8,V_R8,100.0001e+0,"0.0000E+0",S_OK,"1.0000E+2"); VARFMT(VT_R8,V_R8,1000001,"0.0000e+1",S_OK,"1.0000e+61"); VARFMT(VT_R8,V_R8,100.0001e+25,"0.0000e+0",S_OK,"1.0000e+27"); VARFMT(VT_R8,V_R8,450.0001e+43,"#000.0000e+0",S_OK,"4500.0010e+42"); } /* 'out' is not cleared */ out = (BSTR)0x1; pVarFormat(&in,NULL,fd,fw,flags,&out); /* Would crash if out is cleared */ out = NULL; /* Invalid args */ hres = pVarFormat(&in,NULL,fd,fw,flags,NULL); ok(hres == E_INVALIDARG, "Null out: expected E_INVALIDARG, got 0x%08lx\n", hres); hres = pVarFormat(NULL,NULL,fd,fw,flags,&out); ok(hres == E_INVALIDARG, "Null in: expected E_INVALIDARG, got 0x%08lx\n", hres); fd = -1; VARFMT(VT_BOOL,V_BOOL,VARIANT_TRUE,"",E_INVALIDARG,""); fd = 8; VARFMT(VT_BOOL,V_BOOL,VARIANT_TRUE,"",E_INVALIDARG,""); fd = 0; fw = -1; VARFMT(VT_BOOL,V_BOOL,VARIANT_TRUE,"",E_INVALIDARG,""); fw = 4; VARFMT(VT_BOOL,V_BOOL,VARIANT_TRUE,"",E_INVALIDARG,""); } static HRESULT (WINAPI *pVarAbs)(LPVARIANT,LPVARIANT); static const char *szVarAbsFail = "VarAbs: expected 0x0,%d,%d, got 0x%lX,%d,%d\n"; #define VARABS(vt,val,rvt,rval) V_VT(&v) = VT_##vt; V_##vt(&v) = val; \ memset(&vDst,0,sizeof(vDst)); hres = pVarAbs(&v,&vDst); \ ok(hres == S_OK && V_VT(&vDst) == VT_##rvt && V_##rvt(&vDst) == (rval), \ szVarAbsFail, VT_##rvt, (int)(rval), \ hres, V_VT(&vDst), (int)V_##rvt(&vDst)) static void test_VarAbs(void) { static const WCHAR szNum[] = {'-','1','.','1','\0' }; char buff[8]; HRESULT hres; VARIANT v, vDst; size_t i; CHECKPTR(VarAbs); /* Test all possible V_VT values. */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]); i++) { VARTYPE vt; for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { HRESULT hExpected = DISP_E_BADVARTYPE; SKIPTESTS(vt); memset(&v, 0, sizeof(v)); V_VT(&v) = vt | ExtraFlags[i]; V_VT(&vDst) = VT_EMPTY; hres = pVarAbs(&v,&vDst); if (ExtraFlags[i] & (VT_ARRAY|VT_ARRAY) || (!ExtraFlags[i] && (vt == VT_UNKNOWN || vt == VT_BSTR || vt == VT_DISPATCH || vt == VT_ERROR || vt == VT_RECORD))) { hExpected = DISP_E_TYPEMISMATCH; } else if (ExtraFlags[i] || vt >= VT_CLSID || vt == VT_VARIANT) { hExpected = DISP_E_BADVARTYPE; } else if (IsValidVariantClearVT(vt, ExtraFlags[i])) hExpected = S_OK; /* Native always fails on some vartypes that should be valid. don't * check that Wine does the same; these are bugs in native. */ if (vt == VT_I8 || vt == VT_UI8 || vt == VT_INT || vt == VT_UINT || vt == VT_I1 || vt == VT_UI2 || vt == VT_UI4) continue; ok(hres == hExpected, "VarAbs: expected 0x%lX, got 0x%lX for vt %d | 0x%X\n", hExpected, hres, vt, ExtraFlags[i]); } } /* BOOL->I2, BSTR->R8, all others remain the same */ VARABS(BOOL,VARIANT_TRUE,I2,-VARIANT_TRUE); VARABS(BOOL,VARIANT_FALSE,I2,VARIANT_FALSE); VARABS(EMPTY,0,I2,0); VARABS(EMPTY,1,I2,0); VARABS(NULL,0,NULL,0); VARABS(NULL,1,NULL,0); VARABS(I2,1,I2,1); VARABS(I2,-1,I2,1); VARABS(I4,1,I4,1); VARABS(I4,-1,I4,1); VARABS(UI1,1,UI1,1); VARABS(R4,1,R4,1); VARABS(R4,-1,R4,1); VARABS(R8,1,R8,1); VARABS(R8,-1,R8,1); VARABS(DATE,1,DATE,1); VARABS(DATE,-1,DATE,1); V_VT(&v) = VT_CY; V_CY(&v).int64 = -10000; memset(&vDst,0,sizeof(vDst)); hres = pVarAbs(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_CY && V_CY(&vDst).int64 == 10000, "VarAbs(CY): expected 0x0 got 0x%lX\n", hres); GetLocaleInfoA(LOCALE_USER_DEFAULT, LOCALE_SDECIMAL, buff, sizeof(buff)/sizeof(char)); if (buff[0] != '.' || buff[1]) { trace("Skipping VarAbs(BSTR) as decimal separator is '%s'\n", buff); return; } V_VT(&v) = VT_BSTR; V_BSTR(&v) = (BSTR)szNum; memset(&vDst,0,sizeof(vDst)); hres = pVarAbs(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_R8 && V_R8(&vDst) == 1.1, "VarAbs: expected 0x0,%d,%g, got 0x%lX,%d,%g\n", VT_R8, 1.1, hres, V_VT(&vDst), V_R8(&vDst)); } static HRESULT (WINAPI *pVarNot)(LPVARIANT,LPVARIANT); static const char *szVarNotFail = "VarNot: expected 0x0,%d,%d, got 0x%lX,%d,%d\n"; #define VARNOT(vt,val,rvt,rval) V_VT(&v) = VT_##vt; V_##vt(&v) = val; \ memset(&vDst,0,sizeof(vDst)); hres = pVarNot(&v,&vDst); \ ok(hres == S_OK && V_VT(&vDst) == VT_##rvt && V_##rvt(&vDst) == (rval), \ szVarNotFail, VT_##rvt, (int)(rval), \ hres, V_VT(&vDst), (int)V_##rvt(&vDst)) static void test_VarNot(void) { static const WCHAR szNum0[] = {'0','\0' }; static const WCHAR szNum1[] = {'1','\0' }; HRESULT hres; VARIANT v, vDst; DECIMAL *pdec = &V_DECIMAL(&v); CY *pcy = &V_CY(&v); size_t i; CHECKPTR(VarNot); /* Test all possible V_VT values */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]); i++) { VARTYPE vt; for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { HRESULT hExpected = DISP_E_BADVARTYPE; SKIPTESTS(vt); memset(&v, 0, sizeof(v)); V_VT(&v) = vt | ExtraFlags[i]; V_VT(&vDst) = VT_EMPTY; switch (V_VT(&v)) { case VT_I1: case VT_UI1: case VT_I2: case VT_UI2: case VT_INT: case VT_UINT: case VT_I4: case VT_UI4: case VT_R4: case VT_R8: case VT_DECIMAL: case VT_BOOL: case VT_NULL: case VT_EMPTY: case VT_DATE: case VT_CY: hExpected = S_OK; break; case VT_I8: case VT_UI8: if (HAVE_OLEAUT32_I8) hExpected = S_OK; break; case VT_RECORD: if (HAVE_OLEAUT32_RECORD) hExpected = DISP_E_TYPEMISMATCH; break; case VT_UNKNOWN: case VT_BSTR: case VT_DISPATCH: case VT_ERROR: hExpected = DISP_E_TYPEMISMATCH; break; default: if (IsValidVariantClearVT(vt, ExtraFlags[i]) && vt != VT_CLSID) hExpected = DISP_E_TYPEMISMATCH; break; } hres = pVarNot(&v,&vDst); ok(hres == hExpected, "VarNot: expected 0x%lX, got 0x%lX vt %d|0x%X\n", hExpected, hres, vt, ExtraFlags[i]); } } /* Test the values returned by all cases that can succeed */ VARNOT(EMPTY,0,I2,-1); VARNOT(EMPTY,1,I2,-1); VARNOT(NULL,0,NULL,0); VARNOT(NULL,1,NULL,0); VARNOT(BOOL,VARIANT_TRUE,BOOL,VARIANT_FALSE); VARNOT(BOOL,VARIANT_FALSE,BOOL,VARIANT_TRUE); VARNOT(I1,-1,I4,0); VARNOT(I1,0,I4,-1); VARNOT(I2,-1,I2,0); VARNOT(I2,0,I2,-1); VARNOT(I2,1,I2,-2); VARNOT(I4,1,I4,-2); VARNOT(I4,0,I4,-1); VARNOT(UI1,1,UI1,254); VARNOT(UI1,0,UI1,255); VARNOT(UI2,0,I4,-1); VARNOT(UI2,1,I4,-2); VARNOT(UI4,0,I4,-1); VARNOT(UI4,1,I4,-2); VARNOT(INT,0,I4,-1); VARNOT(INT,1,I4,-2); VARNOT(UINT,0,I4,-1); VARNOT(UINT,1,I4,-2); if (HAVE_OLEAUT32_I8) { VARNOT(I8,1,I8,-2); VARNOT(I8,0,I8,-1); VARNOT(UI8,0,I4,-1); VARNOT(UI8,1,I4,-2); } VARNOT(R4,1,I4,-2); VARNOT(R4,0,I4,-1); VARNOT(R8,1,I4,-2); VARNOT(R8,0,I4,-1); VARNOT(DATE,1,I4,-2); VARNOT(DATE,0,I4,-1); VARNOT(BSTR,(BSTR)szNum0,I4,-1); ok(V_VT(&v) == VT_BSTR && V_BSTR(&v) == szNum0, "VarNot(0): changed input\n"); VARNOT(BSTR,(BSTR)szNum1,I4,-2); ok(V_VT(&v) == VT_BSTR && V_BSTR(&v) == szNum1, "VarNot(1): changed input\n"); V_VT(&v) = VT_DECIMAL; S(U(*pdec)).sign = DECIMAL_NEG; S(U(*pdec)).scale = 0; pdec->Hi32 = 0; S1(U1(*pdec)).Mid32 = 0; S1(U1(*pdec)).Lo32 = 1; VARNOT(DECIMAL,*pdec,I4,0); pcy->int64 = 10000; VARNOT(CY,*pcy,I4,-2); pcy->int64 = 0; VARNOT(CY,*pcy,I4,-1); pcy->int64 = -1; VARNOT(CY,*pcy,I4,-1); } static HRESULT (WINAPI *pVarSub)(LPVARIANT,LPVARIANT,LPVARIANT); static void test_VarSub(void) { VARIANT va, vb, vc; HRESULT hr; CHECKPTR(VarSub); V_VT(&va) = VT_DATE; V_DATE(&va) = 200000.0; V_VT(&vb) = VT_DATE; V_DATE(&vb) = 100000.0; hr = pVarSub(&va, &vb, &vc); ok(hr == S_OK,"VarSub of VT_DATE - VT_DATE failed with %lx\n", hr); ok(V_VT(&vc) == VT_R8,"VarSub of VT_DATE - VT_DATE returned vt 0x%x\n", V_VT(&vc)); ok(((V_R8(&vc) > 99999.9) && (V_R8(&vc) < 100000.1)),"VarSub of VT_DATE - VT_DATE should return 100000.0, but returned %g\n", V_R8(&vc)); /* fprintf(stderr,"VarSub of 10000-20000 returned: %g\n", V_R8(&vc)); */ } static const char *szVarModFail = "VarMod: expected 0x%lx,%d(%s),%d, got 0x%lX,%d(%s),%d\n"; #define VARMOD(vt1,vt2,val1,val2,rvt,rval,hexpected) V_VT(&v1) = VT_##vt1; V_##vt1(&v1) = val1; \ V_VT(&v2) = VT_##vt2; V_##vt2(&v2) = val2; \ memset(&vDst,0,sizeof(vDst)); hres = pVarMod(&v1,&v2,&vDst); \ ok(hres == hexpected && V_VT(&vDst) == VT_##rvt && V_##rvt(&vDst) == (rval), \ szVarModFail, hexpected, VT_##rvt, vtstr(VT_##rvt), (int)(rval), \ hres, V_VT(&vDst), vtstr(V_VT(&vDst)), (int)V_##rvt(&vDst)) static const char *szVarMod2Fail = "VarMod: expected 0x%lx,%d(%s),%d, got 0x%lX,%d(%s),%d\n"; #define VARMOD2(vt1,vt2,val1,val2,rvt,rval,hexpected) V_VT(&v1) = VT_##vt1; V_I4(&v1) = val1; \ V_VT(&v2) = VT_##vt2; V_I4(&v2) = val2; \ memset(&vDst,0,sizeof(vDst)); hres = pVarMod(&v1,&v2,&vDst); \ ok(hres == hexpected && V_VT(&vDst) == VT_##rvt && V_I4(&vDst) == (rval), \ szVarMod2Fail, hexpected, VT_##rvt, vtstr(VT_##rvt), (int)(rval), \ hres, V_VT(&vDst), vtstr(V_VT(&vDst)), (int)V_I4(&vDst)) static HRESULT (WINAPI *pVarMod)(LPVARIANT,LPVARIANT,LPVARIANT); static void test_VarMod(void) { VARIANT v1, v2, vDst; HRESULT hres; HRESULT hexpected = 0; static const WCHAR szNum0[] = {'1','2','5','\0'}; static const WCHAR szNum1[] = {'1','0','\0'}; int l, r; BOOL lFound, rFound; BOOL lValid, rValid; BSTR strNum0, strNum1; CHECKPTR(VarMod); VARMOD(I1,BOOL,100,10,I4,0,S_OK); VARMOD(I1,I1,100,10,I4,0,S_OK); VARMOD(I1,UI1,100,10,I4,0,S_OK); VARMOD(I1,I2,100,10,I4,0,S_OK); VARMOD(I1,UI2,100,10,I4,0,S_OK); VARMOD(I1,I4,100,10,I4,0,S_OK); VARMOD(I1,UI4,100,10,I4,0,S_OK); VARMOD(I1,R4,100,10,I4,0,S_OK); VARMOD(I1,R8,100,10,I4,0,S_OK); VARMOD(UI1,BOOL,100,10,I2,0,S_OK); VARMOD(UI1,I1,100,10,I4,0,S_OK); VARMOD(UI1,UI1,100,10,UI1,0,S_OK); VARMOD(UI1,I2,100,10,I2,0,S_OK); VARMOD(UI1,UI2,100,10,I4,0,S_OK); VARMOD(UI1,I4,100,10,I4,0,S_OK); VARMOD(UI1,UI4,100,10,I4,0,S_OK); VARMOD(UI1,R4,100,10,I4,0,S_OK); VARMOD(UI1,R8,100,10,I4,0,S_OK); VARMOD(I2,BOOL,100,10,I2,0,S_OK); VARMOD(I2,I1,100,10,I4,0,S_OK); VARMOD(I2,UI1,100,10,I2,0,S_OK); VARMOD(I2,I2,100,10,I2,0,S_OK); VARMOD(I2,UI2,100,10,I4,0,S_OK); VARMOD(I2,I4,100,10,I4,0,S_OK); VARMOD(I2,UI4,100,10,I4,0,S_OK); VARMOD(I2,R4,100,10,I4,0,S_OK); VARMOD(I2,R8,100,10,I4,0,S_OK); VARMOD(I4,BOOL,100,10,I4,0,S_OK); VARMOD(I4,I1,100,10,I4,0,S_OK); VARMOD(I4,UI1,100,10,I4,0,S_OK); VARMOD(I4,I2,100,10,I4,0,S_OK); VARMOD(I4,UI2,100,10,I4,0,S_OK); VARMOD(I4,I4,100,10,I4,0,S_OK); VARMOD(I4,UI4,100,10,I4,0,S_OK); VARMOD(I4,R4,100,10,I4,0,S_OK); VARMOD(I4,R8,100,10,I4,0,S_OK); VARMOD(UI4,BOOL,100,10,I4,0,S_OK); VARMOD(UI4,I1,100,10,I4,0,S_OK); VARMOD(UI4,UI1,100,10,I4,0,S_OK); VARMOD(UI4,I2,100,10,I4,0,S_OK); VARMOD(UI4,UI2,100,10,I4,0,S_OK); VARMOD(UI4,I4,100,10,I4,0,S_OK); VARMOD(UI4,UI4,100,10,I4,0,S_OK); VARMOD(UI4,R4,100,10,I4,0,S_OK); VARMOD(UI4,R8,100,10,I4,0,S_OK); VARMOD(R4,BOOL,100,10,I4,0,S_OK); VARMOD(R4,I1,100,10,I4,0,S_OK); VARMOD(R4,UI1,100,10,I4,0,S_OK); VARMOD(R4,I2,100,10,I4,0,S_OK); VARMOD(R4,UI2,100,10,I4,0,S_OK); VARMOD(R4,I4,100,10,I4,0,S_OK); VARMOD(R4,UI4,100,10,I4,0,S_OK); VARMOD(R4,R4,100,10,I4,0,S_OK); VARMOD(R4,R8,100,10,I4,0,S_OK); VARMOD(R8,BOOL,100,10,I4,0,S_OK); VARMOD(R8,I1,100,10,I4,0,S_OK); VARMOD(R8,UI1,100,10,I4,0,S_OK); VARMOD(R8,I2,100,10,I4,0,S_OK); VARMOD(R8,UI2,100,10,I4,0,S_OK); VARMOD(R8,I4,100,10,I4,0,S_OK); VARMOD(R8,UI4,100,10,I4,0,S_OK); VARMOD(R8,R4,100,10,I4,0,S_OK); VARMOD(R8,R8,100,10,I4,0,S_OK); VARMOD(INT,INT,100,10,I4,0,S_OK); VARMOD(INT,UINT,100,10,I4,0,S_OK); VARMOD(BOOL,BOOL,100,10,I2,0,S_OK); VARMOD(BOOL,I1,100,10,I4,0,S_OK); VARMOD(BOOL,UI1,100,10,I2,0,S_OK); VARMOD(BOOL,I2,100,10,I2,0,S_OK); VARMOD(BOOL,UI2,100,10,I4,0,S_OK); VARMOD(BOOL,I4,100,10,I4,0,S_OK); VARMOD(BOOL,UI4,100,10,I4,0,S_OK); VARMOD(BOOL,R4,100,10,I4,0,S_OK); VARMOD(BOOL,R8,100,10,I4,0,S_OK); VARMOD(BOOL,DATE,100,10,I4,0,S_OK); VARMOD(DATE,BOOL,100,10,I4,0,S_OK); VARMOD(DATE,I1,100,10,I4,0,S_OK); VARMOD(DATE,UI1,100,10,I4,0,S_OK); VARMOD(DATE,I2,100,10,I4,0,S_OK); VARMOD(DATE,UI2,100,10,I4,0,S_OK); VARMOD(DATE,I4,100,10,I4,0,S_OK); VARMOD(DATE,UI4,100,10,I4,0,S_OK); VARMOD(DATE,R4,100,10,I4,0,S_OK); VARMOD(DATE,R8,100,10,I4,0,S_OK); VARMOD(DATE,DATE,100,10,I4,0,S_OK); strNum0 = SysAllocString(szNum0); strNum1 = SysAllocString(szNum1); VARMOD(BSTR,BSTR,strNum0,strNum1,I4,5,S_OK); VARMOD(BSTR,I1,strNum0,10,I4,5,S_OK); VARMOD(BSTR,I2,strNum0,10,I4,5,S_OK); VARMOD(BSTR,I4,strNum0,10,I4,5,S_OK); VARMOD(BSTR,R4,strNum0,10,I4,5,S_OK); VARMOD(BSTR,R8,strNum0,10,I4,5,S_OK); VARMOD(I4,BSTR,125,strNum1,I4,5,S_OK); if (HAVE_OLEAUT32_I8) { VARMOD(BOOL,I8,100,10,I8,0,S_OK); VARMOD(I1,I8,100,10,I8,0,S_OK); VARMOD(UI1,I8,100,10,I8,0,S_OK); VARMOD(I2,I8,100,10,I8,0,S_OK); VARMOD(I4,I8,100,10,I8,0,S_OK); VARMOD(UI4,I8,100,10,I8,0,S_OK); VARMOD(R4,I8,100,10,I8,0,S_OK); VARMOD(R8,I8,100,10,I8,0,S_OK); VARMOD(DATE,I8,100,10,I8,0,S_OK); VARMOD(I8,BOOL,100,10,I8,0,S_OK); VARMOD(I8,I1,100,10,I8,0,S_OK); VARMOD(I8,UI1,100,10,I8,0,S_OK); VARMOD(I8,I2,100,10,I8,0,S_OK); VARMOD(I8,UI2,100,10,I8,0,S_OK); VARMOD(I8,I4,100,10,I8,0,S_OK); VARMOD(I8,UI4,100,10,I8,0,S_OK); VARMOD(I8,R4,100,10,I8,0,S_OK); VARMOD(I8,R8,100,10,I8,0,S_OK); VARMOD(I8,I8,100,10,I8,0,S_OK); VARMOD(BSTR,I8,strNum0,10,I8,5,S_OK); } /* test all combinations of types */ for(l = 0; l < VT_BSTR_BLOB; l++) { SKIPTESTS(l); for(r = 0; r < VT_BSTR_BLOB; r++) { SKIPTESTS(r); if(l == VT_BSTR) continue; if(l == VT_DISPATCH) continue; if(r == VT_BSTR) continue; if(r == VT_DISPATCH) continue; lFound = TRUE; lValid = TRUE; switch(l) { case VT_EMPTY: case VT_NULL: case VT_I1: case VT_UI1: case VT_I2: case VT_UI2: case VT_I4: case VT_I8: case VT_UI4: case VT_UI8: case VT_INT: case VT_UINT: case VT_R4: case VT_R8: case VT_BOOL: case VT_DATE: case VT_CY: hexpected = S_OK; break; case VT_ERROR: case VT_VARIANT: case VT_UNKNOWN: case VT_DECIMAL: case VT_RECORD: lValid = FALSE; break; default: lFound = FALSE; hexpected = DISP_E_BADVARTYPE; break; } rFound = TRUE; rValid = TRUE; switch(r) { case VT_EMPTY: case VT_NULL: case VT_I1: case VT_UI1: case VT_I2: case VT_UI2: case VT_I4: case VT_I8: case VT_UI4: case VT_UI8: case VT_INT: case VT_UINT: case VT_R4: case VT_R8: case VT_BOOL: case VT_DATE: case VT_CY: hexpected = S_OK; break; case VT_ERROR: case VT_VARIANT: case VT_UNKNOWN: case VT_DECIMAL: case VT_RECORD: rValid = FALSE; break; default: rFound = FALSE; break; } if(((l == VT_I8) && (r == VT_INT)) || ((l == VT_INT) && (r == VT_I8))) { hexpected = DISP_E_TYPEMISMATCH; } else if((l == VT_EMPTY) && (r == VT_NULL)) { hexpected = S_OK; } else if((l == VT_NULL) && (r == VT_EMPTY)) { hexpected = S_OK; } else if((l == VT_EMPTY) && (r == VT_CY)) { hexpected = S_OK; } else if((l == VT_EMPTY) && (r == VT_RECORD)) { hexpected = DISP_E_TYPEMISMATCH; } else if((r == VT_EMPTY) && lFound && lValid) { hexpected = DISP_E_DIVBYZERO; } else if((l == VT_ERROR) || ((r == VT_ERROR) && lFound && lValid)) { hexpected = DISP_E_TYPEMISMATCH; } else if((l == VT_NULL) && (r == VT_NULL)) { hexpected = S_OK; } else if((l == VT_VARIANT) || ((r == VT_VARIANT) && lFound && lValid)) { hexpected = DISP_E_TYPEMISMATCH; } else if((l == VT_NULL) && (r == VT_RECORD)) { hexpected = DISP_E_TYPEMISMATCH; } else if((l == VT_NULL) && (r == VT_DECIMAL)) { hexpected = DISP_E_OVERFLOW; } else if((l == VT_UNKNOWN) || ((r == VT_UNKNOWN) && lFound && lValid)) { hexpected = DISP_E_TYPEMISMATCH; } else if((l == VT_NULL) && rFound) { hexpected = S_OK; } else if((l == VT_DECIMAL) || ((r == VT_DECIMAL) && lFound && lValid)) { hexpected = DISP_E_OVERFLOW; } else if(l == VT_RECORD) { hexpected = DISP_E_TYPEMISMATCH; } else if((r == VT_RECORD) && lValid && lFound) { hexpected = DISP_E_TYPEMISMATCH; } else if((l == VT_EMPTY) && (r == VT_EMPTY)) { hexpected = DISP_E_DIVBYZERO; } else if((l == VT_CY) && !rFound) { hexpected = DISP_E_BADVARTYPE; } else if(lFound && !rFound) { hexpected = DISP_E_BADVARTYPE; } else if(!lFound && rFound) { hexpected = DISP_E_BADVARTYPE; } else if((r == VT_NULL) && lFound && lValid) { hexpected = S_OK; } else if((l == VT_NULL) || (r == VT_NULL)) { hexpected = DISP_E_BADVARTYPE; } else if((l == VT_VARIANT) || (r == VT_VARIANT)) { hexpected = DISP_E_BADVARTYPE; } else if(lFound && !rFound) { hexpected = DISP_E_BADVARTYPE; } else if(!lFound && !rFound) { hexpected = DISP_E_BADVARTYPE; } V_VT(&v1) = l; V_VT(&v2) = r; if(l == VT_CY) V_CY(&v1).int64 = 1000000; else if(l == VT_R4) V_R4(&v1) = 100; else if(l == VT_R8) V_R8(&v1) = 100; else if(l == VT_UI8) V_UI8(&v1) = 100; else if(l == VT_DATE) V_DATE(&v1) = 1000; else V_I4(&v1) = 10000; if(r == VT_CY) V_CY(&v2).int64 = 10000; else if(r == VT_R4) V_R4(&v2) = 100; else if(r == VT_R8) V_R8(&v2) = 100; else if(r == VT_UI8) V_UI8(&v2) = 100; else if(r == VT_DATE) V_DATE(&v2) = 1000; else V_I4(&v2) = 10000; if ((l != VT_I8 && l != VT_UI8 && r != VT_I8 && r != VT_UI8) || HAVE_OLEAUT32_I8) { hres = pVarMod(&v1,&v2,&vDst); ok(hres == hexpected, "VarMod: expected 0x%lx, got 0x%lX for l type of %d, r type of %d,\n", hexpected, hres, l, r); } } } /****************************/ /* test some bad parameters */ VARMOD(I4,I4,-1,-1,I4,0,S_OK); /* test modulus with zero */ VARMOD2(I4,I4,100,0,EMPTY,0,DISP_E_DIVBYZERO); VARMOD(I4,I4,0,10,I4,0,S_OK); /* test 0 mod 10 */ /* right parameter is type empty */ VARMOD2(I4,EMPTY,100,10,EMPTY,0,DISP_E_DIVBYZERO); /* left parameter is type empty */ VARMOD2(EMPTY,I4,100,10,I4,0,S_OK); /* mod with a null left value */ VARMOD2(NULL,I4,125,10,NULL,0,S_OK); /* mod with a null right value */ VARMOD2(I4,NULL,100,10,NULL,0,S_OK); /* void left value */ VARMOD2(VOID,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); /* void right value */ VARMOD2(I4,VOID,100,10,EMPTY,0,DISP_E_BADVARTYPE); /* null left value, void right value */ VARMOD2(NULL,VOID,100,10,EMPTY, 0, DISP_E_BADVARTYPE); /* void left value, null right value */ VARMOD2(VOID,NULL,100,10,EMPTY,0,DISP_E_BADVARTYPE); /* some currencies */ V_VT(&v1) = VT_CY; V_VT(&v2) = VT_CY; V_CY(&v1).int64 = 100000; V_CY(&v2).int64 = 100000; hres = pVarMod(&v1,&v2,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_I4 && V_I4(&vDst) == 0, "VarMod: expected 0x%lx,%d,%d, got 0x%lX,%d,%ld\n", S_OK, VT_I4, 0, hres, V_VT(&vDst), V_I4(&vDst)); V_VT(&v1) = VT_I4; V_VT(&v2) = VT_CY; V_I4(&v1) = 100; V_CY(&v2).int64 = 100000; hres = pVarMod(&v1,&v2,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_I4 && V_I4(&vDst) == 0, "VarMod: expected 0x%lx,%d,%d, got 0x%lX,%d,%ld\n", S_OK, VT_I4, 0, hres, V_VT(&vDst), V_I4(&vDst)); VARMOD2(UINT,I4,100,10,I4,0,S_OK); /* test that an error results in the type of the result changing but not its value */ V_VT(&v1) = VT_UNKNOWN; V_VT(&v2) = VT_EMPTY; V_I4(&v1) = 100; V_CY(&v2).int64 = 100000; V_VT(&vDst) = VT_I4; V_I4(&vDst) = 1231; hres = pVarMod(&v1,&v2,&vDst); ok(hres == DISP_E_TYPEMISMATCH && V_VT(&vDst) == VT_EMPTY && V_I4(&vDst) == 1231, "VarMod: expected 0x%lx,%d,%d, got 0x%lX,%d,%ld\n", DISP_E_TYPEMISMATCH, VT_EMPTY, 1231, hres, V_VT(&vDst), V_I4(&vDst)); /* test some invalid types */ /*TODO: not testing VT_DISPATCH */ if (HAVE_OLEAUT32_I8) { VARMOD2(I8,INT,100,10,EMPTY,0,DISP_E_TYPEMISMATCH); } VARMOD2(ERROR,I4,100,10,EMPTY,0,DISP_E_TYPEMISMATCH); VARMOD2(VARIANT,I4,100,10,EMPTY,0,DISP_E_TYPEMISMATCH); VARMOD2(UNKNOWN,I4,100,10,EMPTY,0,DISP_E_TYPEMISMATCH); VARMOD2(DECIMAL,I4,100,10,EMPTY,0,DISP_E_OVERFLOW); VARMOD2(VOID,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(HRESULT,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(PTR,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(SAFEARRAY,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(CARRAY,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(USERDEFINED,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(LPSTR,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(LPWSTR,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(RECORD,I4,100,10,EMPTY,0,DISP_E_TYPEMISMATCH); VARMOD2(FILETIME,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(BLOB,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(STREAM,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(STORAGE,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(STREAMED_OBJECT,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(STORED_OBJECT,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(BLOB_OBJECT,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(CF,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(CLSID,CLSID,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(VECTOR,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(ARRAY,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); VARMOD2(BYREF,I4,100,10,EMPTY,0,DISP_E_BADVARTYPE); /* test some more invalid types */ V_VT(&v1) = 456; V_VT(&v2) = 234; V_I4(&v1) = 100; V_I4(&v2)= 10; hres = pVarMod(&v1,&v2,&vDst); ok(hres == DISP_E_BADVARTYPE && V_VT(&vDst) == VT_EMPTY && V_I4(&vDst) == 0, "VarMod: expected 0x%lx,%d,%d, got 0x%lX,%d,%ld\n", DISP_E_BADVARTYPE, VT_EMPTY, 0, hres, V_VT(&vDst), V_I4(&vDst)); } static HRESULT (WINAPI *pVarFix)(LPVARIANT,LPVARIANT); static const char *szVarFixFail = "VarFix: expected 0x0,%d,%d, got 0x%lX,%d,%d\n"; #define VARFIX(vt,val,rvt,rval) V_VT(&v) = VT_##vt; V_##vt(&v) = val; \ memset(&vDst,0,sizeof(vDst)); hres = pVarFix(&v,&vDst); \ ok(hres == S_OK && V_VT(&vDst) == VT_##rvt && V_##rvt(&vDst) == (rval), \ szVarFixFail, VT_##rvt, (int)(rval), \ hres, V_VT(&vDst), (int)V_##rvt(&vDst)) static void test_VarFix(void) { static const WCHAR szNumMinus1[] = {'-','1','\0' }; HRESULT hres; VARIANT v, vDst; DECIMAL *pdec = &V_DECIMAL(&v); CY *pcy = &V_CY(&v); size_t i; CHECKPTR(VarFix); /* Test all possible V_VT values */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]); i++) { VARTYPE vt; for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { HRESULT bFail = TRUE; SKIPTESTS(vt); memset(&v, 0, sizeof(v)); V_VT(&v) = vt | ExtraFlags[i]; V_VT(&vDst) = VT_EMPTY; switch (V_VT(&v)) { case VT_UI1: case VT_I2: case VT_I4: case VT_R4: case VT_R8: case VT_DECIMAL: case VT_BOOL: case VT_NULL: case VT_EMPTY: case VT_DATE: case VT_CY: bFail = FALSE; break; case VT_I8: if (HAVE_OLEAUT32_I8) bFail = FALSE; break; } hres = pVarFix(&v,&vDst); if (bFail) ok(hres == DISP_E_TYPEMISMATCH || hres == DISP_E_BADVARTYPE, "VarFix: expected failure, got 0x%lX vt %d|0x%X\n", hres, vt, ExtraFlags[i]); else ok(hres == S_OK, "VarFix: expected S_OK, got 0x%lX vt %d|0x%X\n", hres, vt, ExtraFlags[i]); } } VARFIX(BOOL,VARIANT_TRUE,I2,VARIANT_TRUE); VARFIX(BOOL,VARIANT_FALSE,I2,0); VARFIX(BOOL,1,I2,1); VARFIX(UI1,1,UI1,1); VARFIX(I2,-1,I2,-1); VARFIX(I4,-1,I4,-1); if (HAVE_OLEAUT32_I8) { VARFIX(I8,-1,I8,-1); } VARFIX(R4,1.4,R4,1); VARFIX(R4,1.5,R4,1); VARFIX(R4,1.6,R4,1); VARFIX(R4,-1.4,R4,-1); VARFIX(R4,-1.5,R4,-1); VARFIX(R4,-1.6,R4,-1); /* DATE & R8 round as for R4 */ VARFIX(DATE,-1,DATE,-1); VARFIX(R8,-1,R8,-1); VARFIX(BSTR,(BSTR)szNumMinus1,R8,-1); V_VT(&v) = VT_EMPTY; hres = pVarFix(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_I2 && V_I2(&vDst) == 0, "VarFix: expected 0x0,%d,0 got 0x%lX,%d,%d\n", VT_EMPTY, hres, V_VT(&vDst), V_I2(&vDst)); V_VT(&v) = VT_NULL; hres = pVarFix(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_NULL, "VarFix: expected 0x0,%d got 0x%lX,%d\n", VT_NULL, hres, V_VT(&vDst)); V_VT(&v) = VT_DECIMAL; S(U(*pdec)).sign = DECIMAL_NEG; S(U(*pdec)).scale = 0; pdec->Hi32 = 0; S1(U1(*pdec)).Mid32 = 0; S1(U1(*pdec)).Lo32 = 1; hres = pVarFix(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_DECIMAL && !memcmp(&v, &vDst, sizeof(v)), "VarFix: expected 0x0,%d,identical, got 0x%lX,%d\n", VT_DECIMAL, hres, V_VT(&vDst)); /* FIXME: Test some fractional decimals when VarDecFix is implemented */ V_VT(&v) = VT_CY; pcy->int64 = -10000; hres = pVarFix(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_CY && V_CY(&vDst).int64 == -10000, "VarFix: VT_CY wrong, hres=0x%lX\n", hres); V_VT(&v) = VT_CY; pcy->int64 = -16000; hres = pVarFix(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_CY && V_CY(&vDst).int64 == -10000, "VarFix: VT_CY wrong, hres=0x%lX\n", hres); } static HRESULT (WINAPI *pVarInt)(LPVARIANT,LPVARIANT); static const char *szVarIntFail = "VarInt: expected 0x0,%d,%d, got 0x%lX,%d,%d\n"; #define VARINT(vt,val,rvt,rval) V_VT(&v) = VT_##vt; V_##vt(&v) = val; \ memset(&vDst,0,sizeof(vDst)); hres = pVarInt(&v,&vDst); \ ok(hres == S_OK && V_VT(&vDst) == VT_##rvt && V_##rvt(&vDst) == (rval), \ szVarIntFail, VT_##rvt, (int)(rval), \ hres, V_VT(&vDst), (int)V_##rvt(&vDst)) static void test_VarInt(void) { static const WCHAR szNumMinus1[] = {'-','1','\0' }; HRESULT hres; VARIANT v, vDst; DECIMAL *pdec = &V_DECIMAL(&v); CY *pcy = &V_CY(&v); size_t i; CHECKPTR(VarInt); /* Test all possible V_VT values */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]); i++) { VARTYPE vt; for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { HRESULT bFail = TRUE; SKIPTESTS(vt); memset(&v, 0, sizeof(v)); V_VT(&v) = vt | ExtraFlags[i]; V_VT(&vDst) = VT_EMPTY; switch (V_VT(&v)) { case VT_UI1: case VT_I2: case VT_I4: case VT_R4: case VT_R8: case VT_DECIMAL: case VT_BOOL: case VT_NULL: case VT_EMPTY: case VT_DATE: case VT_CY: bFail = FALSE; break; case VT_I8: if (HAVE_OLEAUT32_I8) bFail = FALSE; break; } hres = pVarInt(&v,&vDst); if (bFail) ok(hres == DISP_E_TYPEMISMATCH || hres == DISP_E_BADVARTYPE, "VarInt: expected failure, got 0x%lX vt %d|0x%X\n", hres, vt, ExtraFlags[i]); else ok(hres == S_OK, "VarInt: expected S_OK, got 0x%lX vt %d|0x%X\n", hres, vt, ExtraFlags[i]); } } VARINT(BOOL,VARIANT_TRUE,I2,VARIANT_TRUE); VARINT(BOOL,VARIANT_FALSE,I2,0); VARINT(BOOL,1,I2,1); VARINT(UI1,1,UI1,1); VARINT(I2,-1,I2,-1); VARINT(I4,-1,I4,-1); if (HAVE_OLEAUT32_I8) { VARINT(I8,-1,I8,-1); } VARINT(R4,1.4,R4,1); VARINT(R4,1.5,R4,1); VARINT(R4,1.6,R4,1); VARINT(R4,-1.4,R4,-2); /* Note these 3 are different from VarFix */ VARINT(R4,-1.5,R4,-2); VARINT(R4,-1.6,R4,-2); /* DATE & R8 round as for R4 */ VARINT(DATE,-1,DATE,-1); VARINT(R8,-1,R8,-1); VARINT(BSTR,(BSTR)szNumMinus1,R8,-1); V_VT(&v) = VT_EMPTY; hres = pVarInt(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_I2 && V_I2(&vDst) == 0, "VarInt: expected 0x0,%d,0 got 0x%lX,%d,%d\n", VT_EMPTY, hres, V_VT(&vDst), V_I2(&vDst)); V_VT(&v) = VT_NULL; hres = pVarInt(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_NULL, "VarInt: expected 0x0,%d got 0x%lX,%d\n", VT_NULL, hres, V_VT(&vDst)); V_VT(&v) = VT_DECIMAL; S(U(*pdec)).sign = DECIMAL_NEG; S(U(*pdec)).scale = 0; pdec->Hi32 = 0; S1(U1(*pdec)).Mid32 = 0; S1(U1(*pdec)).Lo32 = 1; hres = pVarInt(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_DECIMAL && !memcmp(&v, &vDst, sizeof(v)), "VarInt: expected 0x0,%d,identical, got 0x%lX,%d\n", VT_DECIMAL, hres, V_VT(&vDst)); /* FIXME: Test some fractional decimals when VarDecInt is implemented */ V_VT(&v) = VT_CY; pcy->int64 = -10000; hres = pVarInt(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_CY && V_CY(&vDst).int64 == -10000, "VarInt: VT_CY wrong, hres=0x%lX\n", hres); V_VT(&v) = VT_CY; pcy->int64 = -11000; hres = pVarInt(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_CY && V_CY(&vDst).int64 == -20000, "VarInt: VT_CY wrong, hres=0x%lX %lld\n", hres,V_CY(&vDst).int64); } static HRESULT (WINAPI *pVarNeg)(LPVARIANT,LPVARIANT); static const char *szVarNegFail = "VarNeg: expected 0x0,%d,%d, got 0x%lX,%d,%d\n"; #define VARNEG(vt,val,rvt,rval) V_VT(&v) = VT_##vt; V_##vt(&v) = val; \ memset(&vDst,0,sizeof(vDst)); hres = pVarNeg(&v,&vDst); \ ok(hres == S_OK && V_VT(&vDst) == VT_##rvt && V_##rvt(&vDst) == (rval), \ szVarNegFail, VT_##rvt, (int)(rval), \ hres, V_VT(&vDst), (int)V_##rvt(&vDst)) static void test_VarNeg(void) { static const WCHAR szNumMinus1[] = {'-','1','\0' }; static const WCHAR szNum1[] = {'1','\0' }; HRESULT hres; VARIANT v, vDst; DECIMAL *pdec = &V_DECIMAL(&v); CY *pcy = &V_CY(&v); size_t i; CHECKPTR(VarNeg); /* Test all possible V_VT values. But don't test the exact return values * except for success/failure, since M$ made a hash of them in the * native version. This at least ensures (as with all tests here) that * we will notice if/when new vtypes/flags are added in native. */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]); i++) { VARTYPE vt; for (vt = 0; vt <= VT_BSTR_BLOB; vt++) { HRESULT bFail = TRUE; SKIPTESTS(vt); memset(&v, 0, sizeof(v)); V_VT(&v) = vt | ExtraFlags[i]; V_VT(&vDst) = VT_EMPTY; switch (V_VT(&v)) { case VT_UI1: case VT_I2: case VT_I4: case VT_R4: case VT_R8: case VT_DECIMAL: case VT_BOOL: case VT_NULL: case VT_EMPTY: case VT_DATE: case VT_CY: bFail = FALSE; break; case VT_I8: if (HAVE_OLEAUT32_I8) bFail = FALSE; } hres = pVarNeg(&v,&vDst); if (bFail) ok(hres == DISP_E_TYPEMISMATCH || hres == DISP_E_BADVARTYPE, "VarNeg: expected failure, got 0x%lX vt %d|0x%X\n", hres, vt, ExtraFlags[i]); else ok(hres == S_OK, "VarNeg: expected S_OK, got 0x%lX vt %d|0x%X\n", hres, vt, ExtraFlags[i]); } } VARNEG(BOOL,VARIANT_TRUE,I2,1); VARNEG(BOOL,VARIANT_FALSE,I2,0); VARNEG(BOOL,1,I2,-1); VARNEG(UI1,1,I2,-1); VARNEG(UI1,254,I2,-254); VARNEG(I2,-32768,I4,32768); VARNEG(I2,-1,I2,1); VARNEG(I2,1,I2,-1); VARNEG(I4,-((int)(~0u >> 1)) - 1,R8,-2147483648u); VARNEG(I4,-1,I4,1); VARNEG(I4,1,I4,-1); if (HAVE_OLEAUT32_I8) { VARNEG(I8,1,I8,-1); VARNEG(I8,-1,I8,1); } VARNEG(R4,1,R4,-1); VARNEG(R4,-1,R4,1); VARNEG(DATE,1,DATE,-1); VARNEG(DATE,-1,DATE,1); VARNEG(R8,1,R8,-1); VARNEG(R8,-1,R8,1); VARNEG(BSTR,(BSTR)szNumMinus1,R8,1); VARNEG(BSTR,(BSTR)szNum1,R8,-1); V_VT(&v) = VT_EMPTY; hres = pVarNeg(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_I2 && V_I2(&vDst) == 0, "VarNeg: expected 0x0,%d,0 got 0x%lX,%d,%d\n", VT_EMPTY, hres, V_VT(&vDst), V_I2(&vDst)); V_VT(&v) = VT_NULL; hres = pVarNeg(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_NULL, "VarNeg: expected 0x0,%d got 0x%lX,%d\n", VT_NULL, hres, V_VT(&vDst)); V_VT(&v) = VT_DECIMAL; S(U(*pdec)).sign = DECIMAL_NEG; S(U(*pdec)).scale = 0; pdec->Hi32 = 0; S1(U1(*pdec)).Mid32 = 0; S1(U1(*pdec)).Lo32 = 1; hres = pVarNeg(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_DECIMAL && S(U(V_DECIMAL(&vDst))).sign == 0, "VarNeg: expected 0x0,%d,0x00, got 0x%lX,%d,%02x\n", VT_DECIMAL, hres, V_VT(&vDst), S(U(V_DECIMAL(&vDst))).sign); S(U(*pdec)).sign = 0; hres = pVarNeg(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_DECIMAL && S(U(V_DECIMAL(&vDst))).sign == DECIMAL_NEG, "VarNeg: expected 0x0,%d,0x7f, got 0x%lX,%d,%02x\n", VT_DECIMAL, hres, V_VT(&vDst), S(U(V_DECIMAL(&vDst))).sign); V_VT(&v) = VT_CY; pcy->int64 = -10000; hres = pVarNeg(&v,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_CY && V_CY(&vDst).int64 == 10000, "VarNeg: VT_CY wrong, hres=0x%lX\n", hres); } static HRESULT (WINAPI *pVarRound)(LPVARIANT,int,LPVARIANT); #define VARROUND(vt,val,deci,rvt,rval) V_VT(&v) = VT_##vt; V_##vt(&v) = val; \ memset(&vDst,0,sizeof(vDst)); hres = pVarRound(&v,deci,&vDst); \ ok(hres == S_OK && V_VT(&vDst) == VT_##rvt && V_##rvt(&vDst) == (rval), \ "VarRound: expected 0x0,%d,%d, got 0x%lX,%d,%d\n", VT_##rvt, (int)(rval), \ hres, V_VT(&vDst), (int)V_##rvt(&vDst)) #define VARROUNDF(vt,val,deci,rvt,rval) V_VT(&v) = VT_##vt; V_##vt(&v) = val; \ memset(&vDst,0,sizeof(vDst)); hres = pVarRound(&v,deci,&vDst); \ ok(hres == S_OK && V_VT(&vDst) == VT_##rvt && V_##rvt(&vDst) == (rval), \ "VarRound: expected 0x0,%d,%f, got 0x%lX,%d,%f\n", VT_##rvt, rval, \ hres, V_VT(&vDst), V_##rvt(&vDst)) static void test_VarRound(void) { /* static const WCHAR szNumMin[] = {'-','1','.','4','5','\0' }; static const WCHAR szNum[] = {'1','.','4','5','\0' }; */ HRESULT hres; VARIANT v, vDst; CY *pcy = &V_CY(&v); CHECKPTR(VarRound); /* first check valid integer types */ VARROUND(BOOL,VARIANT_TRUE,0,I2,-1); VARROUND(BOOL,VARIANT_FALSE,0,I2,0); VARROUND(BOOL,1,0,I2,1); VARROUND(UI1,1,0,UI1,1); VARROUND(UI1,254,0,UI1,254); VARROUND(I2,-32768,0,I2,-32768); VARROUND(I2,-1,0,I2,-1); VARROUND(I2,1,0,I2,1); VARROUND(I4,-((int)(~0u >> 1)) - 1,0,I4,-((int)(~0u >> 1)) - 1); VARROUND(I4,-1,0,I4,-1); VARROUND(I4,1,0,I4,1); /* MSDN states that rounding of R4/R8 is dependent on the underlying * bit pattern of the number and so is architecture dependent. In this * case Wine returns .2 (which is more correct) and Native returns .3 */ VARROUNDF(R4,1.0,0,R4,1.0); VARROUNDF(R4,-1.0,0,R4,-1.0); VARROUNDF(R8,1.0,0,R8,1.0); VARROUNDF(R8,-1.0,0,R8,-1.0); /* floating point numbers aren't exactly equal and we can't just * compare the first few digits. todo_wine { VARROUNDF(DATE,1.451,1,DATE,1.5); VARROUNDF(DATE,-1.45,1,DATE,-1.4); VARROUNDF(BSTR,(BSTR)szNumMin,1,R8,-1.40); VARROUNDF(BSTR,(BSTR)szNum,1,R8,1.50); VARROUNDF(R4,1.23456,0,R4,1.0); VARROUNDF(R4,1.23456,1,R4,1.2); VARROUNDF(R4,1.23456,2,R4,1.23); VARROUNDF(R4,1.23456,3,R4,1.235); VARROUNDF(R4,1.23456,4,R4,1.2346); VARROUNDF(R4,-1.23456,0,R4,-1.0); VARROUNDF(R4,-1.23456,1,R4,-1.2); VARROUNDF(R4,-1.23456,2,R4,-1.23); VARROUNDF(R4,-1.23456,3,R4,-1.235); VARROUNDF(R4,-1.23456,4,R4,-1.2346); VARROUNDF(R8,1.23456,0,R8,1.0); VARROUNDF(R8,1.23456,1,R8,1.2); VARROUNDF(R8,1.23456,2,R8,1.23); VARROUNDF(R8,1.23456,3,R8,1.235); VARROUNDF(R8,1.23456,4,R8,1.2346); VARROUNDF(R8,-1.23456,0,R8,-1.0); VARROUNDF(R8,-1.23456,1,R8,-1.2); VARROUNDF(R8,-1.23456,2,R8,-1.23); VARROUNDF(R8,-1.23456,3,R8,-1.235); VARROUNDF(R8,-1.23456,4,R8,-1.2346); } */ V_VT(&v) = VT_EMPTY; hres = pVarRound(&v,0,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_I2 && V_I2(&vDst) == 0, "VarRound: expected 0x0,%d,0 got 0x%lX,%d,%d\n", VT_EMPTY, hres, V_VT(&vDst), V_I2(&vDst)); V_VT(&v) = VT_NULL; hres = pVarRound(&v,0,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_NULL, "VarRound: expected 0x0,%d got 0x%lX,%d\n", VT_NULL, hres, V_VT(&vDst)); /* not yet implemented so no use testing yet todo_wine { DECIMAL *pdec = &V_DECIMAL(&v); V_VT(&v) = VT_DECIMAL; S(U(*pdec)).sign = DECIMAL_NEG; S(U(*pdec)).scale = 0; pdec->Hi32 = 0; S1(U1(*pdec)).Mid32 = 0; S1(U1(*pdec)).Lo32 = 1; hres = pVarRound(&v,0,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_DECIMAL && S(U(V_DECIMAL(&vDst))).sign == 0, "VarRound: expected 0x0,%d,0x00, got 0x%lX,%d,%02x\n", VT_DECIMAL, hres, V_VT(&vDst), S(U(V_DECIMAL(&vDst))).sign); S(U(*pdec)).sign = 0; hres = pVarRound(&v,0,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_DECIMAL && S(U(V_DECIMAL(&vDst))).sign == DECIMAL_NEG, "VarRound: expected 0x0,%d,0x7f, got 0x%lX,%d,%02x\n", VT_DECIMAL, hres, V_VT(&vDst), S(U(V_DECIMAL(&vDst))).sign); } */ V_VT(&v) = VT_CY; pcy->int64 = 10000; hres = pVarRound(&v,0,&vDst); ok(hres == S_OK && V_VT(&vDst) == VT_CY && V_CY(&vDst).int64 == 10000, "VarRound: VT_CY wrong, hres=0x%lX\n", hres); } static HRESULT (WINAPI *pVarXor)(LPVARIANT,LPVARIANT,LPVARIANT); static const char *szVarXorFail = "VarXor(%d,%d): expected 0x0,%d,%d, got 0x%lX,%d,%d\n"; #define VARXOR(vt1,val1,vt2,val2,rvt,rval) \ V_VT(&left) = VT_##vt1; V_##vt1(&left) = val1; \ V_VT(&right) = VT_##vt2; V_##vt2(&right) = val2; \ memset(&result,0,sizeof(result)); hres = pVarXor(&left,&right,&result); \ ok(hres == S_OK && V_VT(&result) == VT_##rvt && V_##rvt(&result) == (rval), \ szVarXorFail, VT_##vt1, VT_##vt2, \ VT_##rvt, (int)(rval), hres, V_VT(&result), (int)V_##rvt(&result)); \ ok(V_VT(&left) == VT_##vt1 && V_##vt1(&left) == val1 && \ V_VT(&right) == VT_##vt2 && V_##vt2(&right) == val2, \ "VarXor(%d,%d): Modified input arguments\n",VT_##vt1,VT_##vt2) #define VARXORCY(vt1,val1,val2,rvt,rval) \ V_VT(&left) = VT_##vt1; V_##vt1(&left) = val1; \ V_VT(&right) = VT_CY; V_CY(&right).int64 = val2; \ memset(&result,0,sizeof(result)); hres = pVarXor(&left,&right,&result); \ ok(hres == S_OK && V_VT(&result) == VT_##rvt && V_##rvt(&result) == (rval), \ "VarXor(%d,%d): expected 0x0,%d,%d, got 0x%lX,%d,%d\n", VT_##vt1, VT_CY, \ VT_##rvt, (int)(rval), hres, V_VT(&result), (int)V_##rvt(&result)); \ ok(V_VT(&left) == VT_##vt1 && V_##vt1(&left) == val1 && \ V_VT(&right) == VT_CY && V_CY(&right).int64 == val2, \ "VarXor(%d,%d): Modified input arguments\n",VT_##vt1,VT_CY) static void test_VarXor(void) { static const WCHAR szFalse[] = { '#','F','A','L','S','E','#','\0' }; static const WCHAR szTrue[] = { '#','T','R','U','E','#','\0' }; VARIANT left, right, result; BSTR lbstr, rbstr; VARTYPE i; HRESULT hres; CHECKPTR(VarXor); /* Test all possible flag/vt combinations & the resulting vt type */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]); i++) { VARTYPE leftvt, rightvt, resvt; for (leftvt = 0; leftvt <= VT_BSTR_BLOB; leftvt++) { SKIPTESTS(leftvt); for (rightvt = 0; rightvt <= VT_BSTR_BLOB; rightvt++) { BOOL bFail = FALSE; SKIPTESTS(rightvt); if (leftvt == VT_BSTR || rightvt == VT_BSTR || leftvt == VT_DISPATCH || rightvt == VT_DISPATCH || leftvt == VT_UNKNOWN || rightvt == VT_UNKNOWN) continue; memset(&left, 0, sizeof(left)); memset(&right, 0, sizeof(right)); V_VT(&left) = leftvt | ExtraFlags[i]; V_VT(&right) = rightvt | ExtraFlags[i]; V_VT(&result) = VT_EMPTY; resvt = VT_I4; if (ExtraFlags[i] & VT_ARRAY || ExtraFlags[i] & VT_BYREF || !IsValidVariantClearVT(leftvt, ExtraFlags[i]) || !IsValidVariantClearVT(rightvt, ExtraFlags[i]) || leftvt == VT_CLSID || rightvt == VT_CLSID || leftvt == VT_RECORD || rightvt == VT_RECORD || leftvt == VT_VARIANT || rightvt == VT_VARIANT || leftvt == VT_ERROR || rightvt == VT_ERROR) { bFail = TRUE; } if (leftvt == VT_EMPTY || rightvt == VT_EMPTY) { if (leftvt == rightvt || leftvt == VT_I2 || rightvt == VT_I2 || leftvt == VT_UI1 || rightvt == VT_UI1 || leftvt == VT_BOOL || rightvt == VT_BOOL) resvt = VT_I2; else if (leftvt == VT_NULL || rightvt == VT_NULL) resvt = VT_NULL; else if (leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_I8; } else if (leftvt == VT_NULL || rightvt == VT_NULL) { resvt = VT_NULL; } else if (leftvt == VT_UI1 || rightvt == VT_UI1) { if (leftvt == rightvt) resvt = VT_UI1; else if (leftvt == rightvt || leftvt == VT_I2 || rightvt == VT_I2 || leftvt == VT_BOOL || rightvt == VT_BOOL) { resvt = VT_I2; } else if (leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_I8; } else if (leftvt == VT_I2 || rightvt == VT_I2) { if (leftvt == rightvt || leftvt == VT_BOOL || rightvt == VT_BOOL) resvt = VT_I2; else if (leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_I8; } else if (leftvt == VT_BOOL && rightvt == VT_BOOL) { resvt = VT_BOOL; } else if (leftvt == VT_I8 || rightvt == VT_I8) { if (leftvt == VT_INT || rightvt == VT_INT) bFail = TRUE; else resvt = VT_I8; } hres = pVarXor(&left, &right, &result); if (bFail) ok(hres == DISP_E_TYPEMISMATCH || hres == DISP_E_BADVARTYPE, "VarXor: %d|0x%X, %d|0x%X: Expected failure, got 0x%lX vt %d\n", leftvt, ExtraFlags[i], rightvt, ExtraFlags[i], hres, V_VT(&result)); else ok(hres == S_OK && V_VT(&result) == resvt, "VarXor: %d|0x%X, %d|0x%X: expected S_OK, vt %d, got 0x%lX vt %d\n", leftvt, ExtraFlags[i], rightvt, ExtraFlags[i], resvt, hres, V_VT(&result)); } } } /* Test returned values * FIXME: Test VT_DECIMAL/VT_DISPATCH */ VARXOR(EMPTY,0,EMPTY,0,I2,0); VARXOR(EMPTY,1,EMPTY,0,I2,0); VARXOR(EMPTY,0,NULL,0,NULL,0); VARXOR(EMPTY,0,I1,0,I4,0); VARXOR(EMPTY,0,I1,1,I4,1); VARXOR(EMPTY,0,UI1,0,I2,0); VARXOR(EMPTY,0,UI1,1,I2,1); VARXOR(EMPTY,0,I2,0,I2,0); VARXOR(EMPTY,0,I2,1,I2,1); VARXOR(EMPTY,0,UI2,0,I4,0); VARXOR(EMPTY,0,UI2,1,I4,1); VARXOR(EMPTY,0,I4,0,I4,0); VARXOR(EMPTY,0,I4,1,I4,1); VARXOR(EMPTY,0,UI4,0,I4,0); VARXOR(EMPTY,0,UI4,1,I4,1); if (HAVE_OLEAUT32_I8) { VARXOR(EMPTY,0,I8,0,I8,0); VARXOR(EMPTY,0,I8,1,I8,1); VARXOR(EMPTY,0,UI8,0,I4,0); VARXOR(EMPTY,0,UI8,1,I4,1); } VARXOR(EMPTY,0,INT,0,I4,0); VARXOR(EMPTY,0,INT,1,I4,1); VARXOR(EMPTY,0,UINT,0,I4,0); VARXOR(EMPTY,0,UINT,1,I4,1); VARXOR(EMPTY,0,BOOL,0,I2,0); VARXOR(EMPTY,0,BOOL,1,I2,1); VARXOR(EMPTY,0,R4,0,I4,0); VARXOR(EMPTY,0,R4,1,I4,1); VARXOR(EMPTY,0,R8,0,I4,0); VARXOR(EMPTY,0,R8,1,I4,1); rbstr = SysAllocString(szFalse); VARXOR(EMPTY,0,BSTR,rbstr,I2,0); rbstr = SysAllocString(szTrue); VARXOR(EMPTY,0,BSTR,rbstr,I2,-1); VARXORCY(EMPTY,0,10000,I4,1); /* NULL OR 0 = NULL. NULL OR n = n */ VARXOR(NULL,0,NULL,0,NULL,0); VARXOR(NULL,1,NULL,0,NULL,0); VARXOR(NULL,0,I1,0,NULL,0); VARXOR(NULL,0,I1,1,NULL,0); VARXOR(NULL,0,UI1,0,NULL,0); VARXOR(NULL,0,UI1,1,NULL,0); VARXOR(NULL,0,I2,0,NULL,0); VARXOR(NULL,0,I2,1,NULL,0); VARXOR(NULL,0,UI2,0,NULL,0); VARXOR(NULL,0,UI2,1,NULL,0); VARXOR(NULL,0,I4,0,NULL,0); VARXOR(NULL,0,I4,1,NULL,0); VARXOR(NULL,0,UI4,0,NULL,0); VARXOR(NULL,0,UI4,1,NULL,0); if (HAVE_OLEAUT32_I8) { VARXOR(NULL,0,I8,0,NULL,0); VARXOR(NULL,0,I8,1,NULL,0); VARXOR(NULL,0,UI8,0,NULL,0); VARXOR(NULL,0,UI8,1,NULL,0); } VARXOR(NULL,0,INT,0,NULL,0); VARXOR(NULL,0,INT,1,NULL,0); VARXOR(NULL,0,UINT,0,NULL,0); VARXOR(NULL,0,UINT,1,NULL,0); VARXOR(NULL,0,BOOL,0,NULL,0); VARXOR(NULL,0,BOOL,1,NULL,0); VARXOR(NULL,0,R4,0,NULL,0); VARXOR(NULL,0,R4,1,NULL,0); VARXOR(NULL,0,R8,0,NULL,0); VARXOR(NULL,0,R8,1,NULL,0); rbstr = SysAllocString(szFalse); VARXOR(NULL,0,BSTR,rbstr,NULL,0); rbstr = SysAllocString(szTrue); VARXOR(NULL,0,BSTR,rbstr,NULL,0); VARXORCY(NULL,0,10000,NULL,0); VARXORCY(NULL,0,0,NULL,0); VARXOR(BOOL,VARIANT_TRUE,BOOL,VARIANT_TRUE,BOOL,VARIANT_FALSE); VARXOR(BOOL,VARIANT_TRUE,BOOL,VARIANT_FALSE,BOOL,VARIANT_TRUE); VARXOR(BOOL,VARIANT_FALSE,BOOL,VARIANT_TRUE,BOOL,VARIANT_TRUE); VARXOR(BOOL,VARIANT_FALSE,BOOL,VARIANT_FALSE,BOOL,VARIANT_FALSE); /* Assume x,y & y,x are the same from now on to reduce the number of tests */ VARXOR(BOOL,VARIANT_TRUE,I1,-1,I4,0); VARXOR(BOOL,VARIANT_TRUE,I1,0,I4,-1); VARXOR(BOOL,VARIANT_FALSE,I1,0,I4,0); VARXOR(BOOL,VARIANT_TRUE,UI1,255,I2,-256); VARXOR(BOOL,VARIANT_TRUE,UI1,0,I2,-1); VARXOR(BOOL,VARIANT_FALSE,UI1,0,I2,0); VARXOR(BOOL,VARIANT_TRUE,I2,-1,I2,0); VARXOR(BOOL,VARIANT_TRUE,I2,0,I2,-1); VARXOR(BOOL,VARIANT_FALSE,I2,0,I2,0); VARXOR(BOOL,VARIANT_TRUE,UI2,65535,I4,-65536); VARXOR(BOOL,VARIANT_TRUE,UI2,0,I4,-1); VARXOR(BOOL,VARIANT_FALSE,UI2,0,I4,0); VARXOR(BOOL,VARIANT_TRUE,I4,-1,I4,0); VARXOR(BOOL,VARIANT_TRUE,I4,0,I4,-1); VARXOR(BOOL,VARIANT_FALSE,I4,0,I4,0); VARXOR(BOOL,VARIANT_TRUE,UI4,0xffffffff,I4,0); VARXOR(BOOL,VARIANT_TRUE,UI4,0,I4,-1); VARXOR(BOOL,VARIANT_FALSE,UI4,0,I4,0); VARXOR(BOOL,VARIANT_TRUE,R4,-1,I4,0); VARXOR(BOOL,VARIANT_TRUE,R4,0,I4,-1); VARXOR(BOOL,VARIANT_FALSE,R4,0,I4,0); VARXOR(BOOL,VARIANT_TRUE,R8,-1,I4,0); VARXOR(BOOL,VARIANT_TRUE,R8,0,I4,-1); VARXOR(BOOL,VARIANT_FALSE,R8,0,I4,0); VARXOR(BOOL,VARIANT_TRUE,DATE,-1,I4,0); VARXOR(BOOL,VARIANT_TRUE,DATE,0,I4,-1); VARXOR(BOOL,VARIANT_FALSE,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VARXOR(BOOL,VARIANT_TRUE,I8,-1,I8,0); VARXOR(BOOL,VARIANT_TRUE,I8,0,I8,-1); VARXOR(BOOL,VARIANT_FALSE,I8,0,I8,0); /* This returns DISP_E_OVERFLOW which indicates that a conversion * to I4 is performed. */ /* VARXOR(BOOL,VARIANT_TRUE,UI8,-1,I4,-1); */ VARXOR(BOOL,VARIANT_TRUE,UI8,0,I4,-1); VARXOR(BOOL,VARIANT_FALSE,UI8,0,I4,0); } VARXOR(BOOL,VARIANT_TRUE,INT,-1,I4,0); VARXOR(BOOL,VARIANT_TRUE,INT,0,I4,-1); VARXOR(BOOL,VARIANT_FALSE,INT,0,I4,0); VARXOR(BOOL,VARIANT_TRUE,UINT,0xffffffff,I4,0); VARXOR(BOOL,VARIANT_TRUE,UINT,0,I4,-1); VARXOR(BOOL,VARIANT_FALSE,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(BOOL,VARIANT_FALSE,BSTR,rbstr,BOOL,VARIANT_FALSE); VARXOR(BOOL,VARIANT_TRUE,BSTR,rbstr,BOOL,VARIANT_TRUE); rbstr = SysAllocString(szTrue); VARXOR(BOOL,VARIANT_FALSE,BSTR,rbstr,BOOL,VARIANT_TRUE); VARXOR(BOOL,VARIANT_TRUE,BSTR,rbstr,BOOL,VARIANT_FALSE); VARXORCY(BOOL,VARIANT_TRUE,10000,I4,-2); VARXORCY(BOOL,VARIANT_TRUE,0,I4,-1); VARXORCY(BOOL,VARIANT_FALSE,0,I4,0); VARXOR(I1,-1,I1,-1,I4,0); VARXOR(I1,-1,I1,0,I4,-1); VARXOR(I1,0,I1,0,I4,0); VARXOR(I1,-1,UI1,255,I4,-256); VARXOR(I1,-1,UI1,0,I4,-1); VARXOR(I1,0,UI1,0,I4,0); VARXOR(I1,-1,I2,-1,I4,0); VARXOR(I1,-1,I2,0,I4,-1); VARXOR(I1,0,I2,0,I4,0); VARXOR(I1,-1,UI2,65535,I4,-65536); VARXOR(I1,-1,UI2,0,I4,-1); VARXOR(I1,0,UI2,0,I4,0); VARXOR(I1,-1,I4,-1,I4,0); VARXOR(I1,-1,I4,0,I4,-1); VARXOR(I1,0,I4,0,I4,0); VARXOR(I1,-1,UI4,0xffffffff,I4,0); VARXOR(I1,-1,UI4,0,I4,-1); VARXOR(I1,0,UI4,0,I4,0); VARXOR(I1,-1,R4,-1,I4,0); VARXOR(I1,-1,R4,0,I4,-1); VARXOR(I1,0,R4,0,I4,0); VARXOR(I1,-1,R8,-1,I4,0); VARXOR(I1,-1,R8,0,I4,-1); VARXOR(I1,0,R8,0,I4,0); VARXOR(I1,-1,DATE,-1,I4,0); VARXOR(I1,-1,DATE,0,I4,-1); VARXOR(I1,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VARXOR(I1,-1,I8,-1,I8,0); VARXOR(I1,-1,I8,0,I8,-1); VARXOR(I1,0,I8,0,I8,0); VARXOR(I1,-1,UI8,0,I4,-1); VARXOR(I1,0,UI8,0,I4,0); } VARXOR(I1,-1,INT,-1,I4,0); VARXOR(I1,-1,INT,0,I4,-1); VARXOR(I1,0,INT,0,I4,0); VARXOR(I1,-1,UINT,0xffffffff,I4,0); VARXOR(I1,-1,UINT,0,I4,-1); VARXOR(I1,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(I1,0,BSTR,rbstr,I4,0); VARXOR(I1,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VARXOR(I1,0,BSTR,rbstr,I4,-1); VARXOR(I1,-1,BSTR,rbstr,I4,0); VARXORCY(I1,-1,10000,I4,-2); VARXORCY(I1,-1,0,I4,-1); VARXORCY(I1,0,0,I4,0); VARXOR(UI1,255,UI1,255,UI1,0); VARXOR(UI1,255,UI1,0,UI1,255); VARXOR(UI1,0,UI1,0,UI1,0); VARXOR(UI1,255,I2,-1,I2,-256); VARXOR(UI1,255,I2,0,I2,255); VARXOR(UI1,0,I2,0,I2,0); VARXOR(UI1,255,UI2,65535,I4,65280); VARXOR(UI1,255,UI2,0,I4,255); VARXOR(UI1,0,UI2,0,I4,0); VARXOR(UI1,255,I4,-1,I4,-256); VARXOR(UI1,255,I4,0,I4,255); VARXOR(UI1,0,I4,0,I4,0); VARXOR(UI1,255,UI4,0xffffffff,I4,-256); VARXOR(UI1,255,UI4,0,I4,255); VARXOR(UI1,0,UI4,0,I4,0); VARXOR(UI1,255,R4,-1,I4,-256); VARXOR(UI1,255,R4,0,I4,255); VARXOR(UI1,0,R4,0,I4,0); VARXOR(UI1,255,R8,-1,I4,-256); VARXOR(UI1,255,R8,0,I4,255); VARXOR(UI1,0,R8,0,I4,0); VARXOR(UI1,255,DATE,-1,I4,-256); VARXOR(UI1,255,DATE,0,I4,255); VARXOR(UI1,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VARXOR(UI1,255,I8,-1,I8,-256); VARXOR(UI1,255,I8,0,I8,255); VARXOR(UI1,0,I8,0,I8,0); VARXOR(UI1,255,UI8,0,I4,255); VARXOR(UI1,0,UI8,0,I4,0); } VARXOR(UI1,255,INT,-1,I4,-256); VARXOR(UI1,255,INT,0,I4,255); VARXOR(UI1,0,INT,0,I4,0); VARXOR(UI1,255,UINT,0xffffffff,I4,-256); VARXOR(UI1,255,UINT,0,I4,255); VARXOR(UI1,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(UI1,0,BSTR,rbstr,I2,0); VARXOR(UI1,255,BSTR,rbstr,I2,255); rbstr = SysAllocString(szTrue); VARXOR(UI1,0,BSTR,rbstr,I2,-1); VARXOR(UI1,255,BSTR,rbstr,I2,-256); VARXORCY(UI1,255,10000,I4,254); VARXORCY(UI1,255,0,I4,255); VARXORCY(UI1,0,0,I4,0); VARXOR(I2,-1,I2,-1,I2,0); VARXOR(I2,-1,I2,0,I2,-1); VARXOR(I2,0,I2,0,I2,0); VARXOR(I2,-1,UI2,65535,I4,-65536); VARXOR(I2,-1,UI2,0,I4,-1); VARXOR(I2,0,UI2,0,I4,0); VARXOR(I2,-1,I4,-1,I4,0); VARXOR(I2,-1,I4,0,I4,-1); VARXOR(I2,0,I4,0,I4,0); VARXOR(I2,-1,UI4,0xffffffff,I4,0); VARXOR(I2,-1,UI4,0,I4,-1); VARXOR(I2,0,UI4,0,I4,0); VARXOR(I2,-1,R4,-1,I4,0); VARXOR(I2,-1,R4,0,I4,-1); VARXOR(I2,0,R4,0,I4,0); VARXOR(I2,-1,R8,-1,I4,0); VARXOR(I2,-1,R8,0,I4,-1); VARXOR(I2,0,R8,0,I4,0); VARXOR(I2,-1,DATE,-1,I4,0); VARXOR(I2,-1,DATE,0,I4,-1); VARXOR(I2,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VARXOR(I2,-1,I8,-1,I8,0); VARXOR(I2,-1,I8,0,I8,-1); VARXOR(I2,0,I8,0,I8,0); VARXOR(I2,-1,UI8,0,I4,-1); VARXOR(I2,0,UI8,0,I4,0); } VARXOR(I2,-1,INT,-1,I4,0); VARXOR(I2,-1,INT,0,I4,-1); VARXOR(I2,0,INT,0,I4,0); VARXOR(I2,-1,UINT,0xffffffff,I4,0); VARXOR(I2,-1,UINT,0,I4,-1); VARXOR(I2,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(I2,0,BSTR,rbstr,I2,0); VARXOR(I2,-1,BSTR,rbstr,I2,-1); rbstr = SysAllocString(szTrue); VARXOR(I2,0,BSTR,rbstr,I2,-1); VARXOR(I2,-1,BSTR,rbstr,I2,0); VARXORCY(I2,-1,10000,I4,-2); VARXORCY(I2,-1,0,I4,-1); VARXORCY(I2,0,0,I4,0); VARXOR(UI2,65535,UI2,65535,I4,0); VARXOR(UI2,65535,UI2,0,I4,65535); VARXOR(UI2,0,UI2,0,I4,0); VARXOR(UI2,65535,I4,-1,I4,-65536); VARXOR(UI2,65535,I4,0,I4,65535); VARXOR(UI2,0,I4,0,I4,0); VARXOR(UI2,65535,UI4,0xffffffff,I4,-65536); VARXOR(UI2,65535,UI4,0,I4,65535); VARXOR(UI2,0,UI4,0,I4,0); VARXOR(UI2,65535,R4,-1,I4,-65536); VARXOR(UI2,65535,R4,0,I4,65535); VARXOR(UI2,0,R4,0,I4,0); VARXOR(UI2,65535,R8,-1,I4,-65536); VARXOR(UI2,65535,R8,0,I4,65535); VARXOR(UI2,0,R8,0,I4,0); VARXOR(UI2,65535,DATE,-1,I4,-65536); VARXOR(UI2,65535,DATE,0,I4,65535); VARXOR(UI2,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VARXOR(UI2,65535,I8,-1,I8,-65536); VARXOR(UI2,65535,I8,0,I8,65535); VARXOR(UI2,0,I8,0,I8,0); VARXOR(UI2,65535,UI8,0,I4,65535); VARXOR(UI2,0,UI8,0,I4,0); } VARXOR(UI2,65535,INT,-1,I4,-65536); VARXOR(UI2,65535,INT,0,I4,65535); VARXOR(UI2,0,INT,0,I4,0); VARXOR(UI2,65535,UINT,0xffffffff,I4,-65536); VARXOR(UI2,65535,UINT,0,I4,65535); VARXOR(UI2,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(UI2,0,BSTR,rbstr,I4,0); VARXOR(UI2,65535,BSTR,rbstr,I4,65535); rbstr = SysAllocString(szTrue); VARXOR(UI2,0,BSTR,rbstr,I4,-1); VARXOR(UI2,65535,BSTR,rbstr,I4,-65536); VARXORCY(UI2,65535,10000,I4,65534); VARXORCY(UI2,65535,0,I4,65535); VARXORCY(UI2,0,0,I4,0); VARXOR(I4,-1,I4,-1,I4,0); VARXOR(I4,-1,I4,0,I4,-1); VARXOR(I4,0,I4,0,I4,0); VARXOR(I4,-1,UI4,0xffffffff,I4,0); VARXOR(I4,-1,UI4,0,I4,-1); VARXOR(I4,0,UI4,0,I4,0); VARXOR(I4,-1,R4,-1,I4,0); VARXOR(I4,-1,R4,0,I4,-1); VARXOR(I4,0,R4,0,I4,0); VARXOR(I4,-1,R8,-1,I4,0); VARXOR(I4,-1,R8,0,I4,-1); VARXOR(I4,0,R8,0,I4,0); VARXOR(I4,-1,DATE,-1,I4,0); VARXOR(I4,-1,DATE,0,I4,-1); VARXOR(I4,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VARXOR(I4,-1,I8,-1,I8,0); VARXOR(I4,-1,I8,0,I8,-1); VARXOR(I4,0,I8,0,I8,0); VARXOR(I4,-1,UI8,0,I4,-1); VARXOR(I4,0,UI8,0,I4,0); } VARXOR(I4,-1,INT,-1,I4,0); VARXOR(I4,-1,INT,0,I4,-1); VARXOR(I4,0,INT,0,I4,0); VARXOR(I4,-1,UINT,0xffffffff,I4,0); VARXOR(I4,-1,UINT,0,I4,-1); VARXOR(I4,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(I4,0,BSTR,rbstr,I4,0); VARXOR(I4,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VARXOR(I4,0,BSTR,rbstr,I4,-1); VARXOR(I4,-1,BSTR,rbstr,I4,0); VARXORCY(I4,-1,10000,I4,-2); VARXORCY(I4,-1,0,I4,-1); VARXORCY(I4,0,0,I4,0); VARXOR(UI4,0xffffffff,UI4,0xffffffff,I4,0); VARXOR(UI4,0xffffffff,UI4,0,I4,-1); VARXOR(UI4,0,UI4,0,I4,0); VARXOR(UI4,0xffffffff,R4,-1,I4,0); VARXOR(UI4,0xffffffff,R4,0,I4,-1); VARXOR(UI4,0,R4,0,I4,0); VARXOR(UI4,0xffffffff,R8,-1,I4,0); VARXOR(UI4,0xffffffff,R8,0,I4,-1); VARXOR(UI4,0,R8,0,I4,0); VARXOR(UI4,0xffffffff,DATE,-1,I4,0); VARXOR(UI4,0xffffffff,DATE,0,I4,-1); VARXOR(UI4,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VARXOR(UI4,0xffffffff,I8,0,I8,0xffffffff); VARXOR(UI4,VARIANT_FALSE,I8,VARIANT_FALSE,I8,0); VARXOR(UI4,0,I8,0,I8,0); VARXOR(UI4,0xffffffff,UI8,0,I4,-1); VARXOR(UI4,0,UI8,0,I4,0); } VARXOR(UI4,0xffffffff,INT,-1,I4,0); VARXOR(UI4,0xffffffff,INT,0,I4,-1); VARXOR(UI4,0,INT,0,I4,0); VARXOR(UI4,0xffffffff,UINT,0xffffffff,I4,0); VARXOR(UI4,0xffffffff,UINT,0,I4,-1); VARXOR(UI4,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(UI4,0,BSTR,rbstr,I4,0); VARXOR(UI4,0xffffffff,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VARXOR(UI4,0,BSTR,rbstr,I4,-1); VARXOR(UI4,0xffffffff,BSTR,rbstr,I4,0); VARXORCY(UI4,0xffffffff,10000,I4,-2); VARXORCY(UI4,0xffffffff,0,I4,-1); VARXORCY(UI4,0,0,I4,0); VARXOR(R4,-1,R4,-1,I4,0); VARXOR(R4,-1,R4,0,I4,-1); VARXOR(R4,0,R4,0,I4,0); VARXOR(R4,-1,R8,-1,I4,0); VARXOR(R4,-1,R8,0,I4,-1); VARXOR(R4,0,R8,0,I4,0); VARXOR(R4,-1,DATE,-1,I4,0); VARXOR(R4,-1,DATE,0,I4,-1); VARXOR(R4,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VARXOR(R4,-1,I8,-1,I8,0); VARXOR(R4,-1,I8,0,I8,-1); VARXOR(R4,0,I8,0,I8,0); VARXOR(R4,-1,UI8,0,I4,-1); VARXOR(R4,0,UI8,0,I4,0); } VARXOR(R4,-1,INT,-1,I4,0); VARXOR(R4,-1,INT,0,I4,-1); VARXOR(R4,0,INT,0,I4,0); VARXOR(R4,-1,UINT,0xffffffff,I4,0); VARXOR(R4,-1,UINT,0,I4,-1); VARXOR(R4,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(R4,0,BSTR,rbstr,I4,0); VARXOR(R4,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VARXOR(R4,0,BSTR,rbstr,I4,-1); VARXOR(R4,-1,BSTR,rbstr,I4,0); VARXORCY(R4,-1,10000,I4,-2); VARXORCY(R4,-1,0,I4,-1); VARXORCY(R4,0,0,I4,0); VARXOR(R8,-1,R8,-1,I4,0); VARXOR(R8,-1,R8,0,I4,-1); VARXOR(R8,0,R8,0,I4,0); VARXOR(R8,-1,DATE,-1,I4,0); VARXOR(R8,-1,DATE,0,I4,-1); VARXOR(R8,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VARXOR(R8,-1,I8,-1,I8,0); VARXOR(R8,-1,I8,0,I8,-1); VARXOR(R8,0,I8,0,I8,0); VARXOR(R8,-1,UI8,0,I4,-1); VARXOR(R8,0,UI8,0,I4,0); } VARXOR(R8,-1,INT,-1,I4,0); VARXOR(R8,-1,INT,0,I4,-1); VARXOR(R8,0,INT,0,I4,0); VARXOR(R8,-1,UINT,0xffffffff,I4,0); VARXOR(R8,-1,UINT,0,I4,-1); VARXOR(R8,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(R8,0,BSTR,rbstr,I4,0); VARXOR(R8,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VARXOR(R8,0,BSTR,rbstr,I4,-1); VARXOR(R8,-1,BSTR,rbstr,I4,0); VARXORCY(R8,-1,10000,I4,-2); VARXORCY(R8,-1,0,I4,-1); VARXORCY(R8,0,0,I4,0); VARXOR(DATE,-1,DATE,-1,I4,0); VARXOR(DATE,-1,DATE,0,I4,-1); VARXOR(DATE,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VARXOR(DATE,-1,I8,-1,I8,0); VARXOR(DATE,-1,I8,0,I8,-1); VARXOR(DATE,0,I8,0,I8,0); VARXOR(DATE,-1,UI8,0,I4,-1); VARXOR(DATE,0,UI8,0,I4,0); } VARXOR(DATE,-1,INT,-1,I4,0); VARXOR(DATE,-1,INT,0,I4,-1); VARXOR(DATE,0,INT,0,I4,0); VARXOR(DATE,-1,UINT,0xffffffff,I4,0); VARXOR(DATE,-1,UINT,0,I4,-1); VARXOR(DATE,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(DATE,0,BSTR,rbstr,I4,0); VARXOR(DATE,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VARXOR(DATE,0,BSTR,rbstr,I4,-1); VARXOR(DATE,-1,BSTR,rbstr,I4,0); VARXORCY(DATE,-1,10000,I4,-2); VARXORCY(DATE,-1,0,I4,-1); VARXORCY(DATE,0,0,I4,0); if (HAVE_OLEAUT32_I8) { VARXOR(I8,-1,I8,-1,I8,0); VARXOR(I8,-1,I8,0,I8,-1); VARXOR(I8,0,I8,0,I8,0); VARXOR(I8,-1,UI8,0,I8,-1); VARXOR(I8,0,UI8,0,I8,0); VARXOR(I8,-1,UINT,0,I8,-1); VARXOR(I8,0,UINT,0,I8,0); rbstr = SysAllocString(szFalse); VARXOR(I8,0,BSTR,rbstr,I8,0); VARXOR(I8,-1,BSTR,rbstr,I8,-1); rbstr = SysAllocString(szTrue); VARXOR(I8,0,BSTR,rbstr,I8,-1); VARXOR(I8,-1,BSTR,rbstr,I8,0); VARXORCY(I8,-1,10000,I8,-2); VARXORCY(I8,-1,0,I8,-1); VARXORCY(I8,0,0,I8,0); VARXOR(UI8,0xffff,UI8,0xffff,I4,0); VARXOR(UI8,0xffff,UI8,0,I4,0xffff); VARXOR(UI8,0,UI8,0,I4,0); VARXOR(UI8,0xffff,INT,-1,I4,-65536); VARXOR(UI8,0xffff,INT,0,I4,0xffff); VARXOR(UI8,0,INT,0,I4,0); VARXOR(UI8,0xffff,UINT,0xffff,I4,0); VARXOR(UI8,0xffff,UINT,0,I4,0xffff); VARXOR(UI8,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(UI8,0,BSTR,rbstr,I4,0); VARXOR(UI8,0xffff,BSTR,rbstr,I4,0xffff); rbstr = SysAllocString(szTrue); VARXOR(UI8,0,BSTR,rbstr,I4,-1); VARXOR(UI8,0xffff,BSTR,rbstr,I4,-65536); VARXORCY(UI8,0xffff,10000,I4,65534); VARXORCY(UI8,0xffff,0,I4,0xffff); VARXORCY(UI8,0,0,I4,0); } VARXOR(INT,-1,INT,-1,I4,0); VARXOR(INT,-1,INT,0,I4,-1); VARXOR(INT,0,INT,0,I4,0); VARXOR(INT,-1,UINT,0xffff,I4,-65536); VARXOR(INT,-1,UINT,0,I4,-1); VARXOR(INT,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(INT,0,BSTR,rbstr,I4,0); VARXOR(INT,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VARXOR(INT,0,BSTR,rbstr,I4,-1); VARXOR(INT,-1,BSTR,rbstr,I4,0); VARXORCY(INT,-1,10000,I4,-2); VARXORCY(INT,-1,0,I4,-1); VARXORCY(INT,0,0,I4,0); VARXOR(UINT,0xffff,UINT,0xffff,I4,0); VARXOR(UINT,0xffff,UINT,0,I4,0xffff); VARXOR(UINT,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VARXOR(UINT,0,BSTR,rbstr,I4,0); VARXOR(UINT,0xffff,BSTR,rbstr,I4,0xffff); rbstr = SysAllocString(szTrue); VARXOR(UINT,0,BSTR,rbstr,I4,-1); VARXOR(UINT,0xffff,BSTR,rbstr,I4,-65536); VARXORCY(UINT,0xffff,10000,I4,65534); VARXORCY(UINT,0xffff,0,I4,0xffff); VARXORCY(UINT,0,0,I4,0); lbstr = SysAllocString(szFalse); rbstr = SysAllocString(szFalse); VARXOR(BSTR,lbstr,BSTR,rbstr,BOOL,0); rbstr = SysAllocString(szTrue); VARXOR(BSTR,lbstr,BSTR,rbstr,BOOL,VARIANT_TRUE); lbstr = SysAllocString(szTrue); VARXOR(BSTR,lbstr,BSTR,rbstr,BOOL,VARIANT_FALSE); VARXORCY(BSTR,lbstr,10000,I4,-2); lbstr = SysAllocString(szFalse); VARXORCY(BSTR,lbstr,10000,I4,1); } static HRESULT (WINAPI *pVarOr)(LPVARIANT,LPVARIANT,LPVARIANT); static const char *szVarOrFail = "VarOr(%d,%d): expected 0x0,%d,%d, got 0x%lX,%d,%d\n"; static const char *szVarOrChanged = "VarOr(%d,%d): Modified input arguments\n"; #define VAROR(vt1,val1,vt2,val2,rvt,rval) \ V_VT(&left) = VT_##vt1; V_##vt1(&left) = val1; \ V_VT(&right) = VT_##vt2; V_##vt2(&right) = val2; \ memset(&result,0,sizeof(result)); hres = pVarOr(&left,&right,&result); \ ok(hres == S_OK && V_VT(&result) == VT_##rvt && V_##rvt(&result) == (rval), \ szVarOrFail, VT_##vt1, VT_##vt2, \ VT_##rvt, (int)(rval), hres, V_VT(&result), (int)V_##rvt(&result)); \ ok(V_VT(&left) == VT_##vt1 && V_##vt1(&left) == val1 && \ V_VT(&right) == VT_##vt2 && V_##vt2(&right) == val2, \ szVarOrChanged,VT_##vt1,VT_##vt2) #define VARORCY(vt1,val1,val2,rvt,rval) \ V_VT(&left) = VT_##vt1; V_##vt1(&left) = val1; \ V_VT(&right) = VT_CY; V_CY(&right).int64 = val2; \ memset(&result,0,sizeof(result)); hres = pVarOr(&left,&right,&result); \ ok(hres == S_OK && V_VT(&result) == VT_##rvt && V_##rvt(&result) == (rval), \ "VarOr(%d,%d): expected 0x0,%d,%d, got 0x%lX,%d,%d\n", VT_##vt1, VT_CY, \ VT_##rvt, (int)(rval), hres, V_VT(&result), (int)V_##rvt(&result)); \ ok(V_VT(&left) == VT_##vt1 && V_##vt1(&left) == val1 && \ V_VT(&right) == VT_CY && V_CY(&right).int64 == val2, \ "VarOr(%d,%d): Modified input arguments\n",VT_##vt1,VT_CY) static void test_VarOr(void) { static const WCHAR szFalse[] = { '#','F','A','L','S','E','#','\0' }; static const WCHAR szTrue[] = { '#','T','R','U','E','#','\0' }; VARIANT left, right, result; BSTR lbstr, rbstr; VARTYPE i; HRESULT hres; CHECKPTR(VarOr); /* Test all possible flag/vt combinations & the resulting vt type */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]); i++) { VARTYPE leftvt, rightvt, resvt; for (leftvt = 0; leftvt <= VT_BSTR_BLOB; leftvt++) { SKIPTESTS(leftvt); for (rightvt = 0; rightvt <= VT_BSTR_BLOB; rightvt++) { BOOL bFail = FALSE; SKIPTESTS(rightvt); if (leftvt == VT_BSTR || rightvt == VT_BSTR || leftvt == VT_DISPATCH || rightvt == VT_DISPATCH || leftvt == VT_UNKNOWN || rightvt == VT_UNKNOWN) continue; memset(&left, 0, sizeof(left)); memset(&right, 0, sizeof(right)); V_VT(&left) = leftvt | ExtraFlags[i]; V_VT(&right) = rightvt | ExtraFlags[i]; V_VT(&result) = VT_EMPTY; resvt = VT_I4; if (ExtraFlags[i] & VT_ARRAY || ExtraFlags[i] & VT_BYREF || !IsValidVariantClearVT(leftvt, ExtraFlags[i]) || !IsValidVariantClearVT(rightvt, ExtraFlags[i]) || leftvt == VT_CLSID || rightvt == VT_CLSID || leftvt == VT_RECORD || rightvt == VT_RECORD || leftvt == VT_VARIANT || rightvt == VT_VARIANT || leftvt == VT_ERROR || rightvt == VT_ERROR) { bFail = TRUE; } if (leftvt == VT_EMPTY || rightvt == VT_EMPTY) { if (leftvt == rightvt || leftvt == VT_I2 || rightvt == VT_I2 || leftvt == VT_UI1 || rightvt == VT_UI1 || leftvt == VT_BOOL || rightvt == VT_BOOL) resvt = VT_I2; else if (leftvt == VT_NULL || rightvt == VT_NULL) resvt = VT_NULL; else if (leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_I8; } else if (leftvt == VT_NULL || rightvt == VT_NULL) { resvt = VT_NULL; } else if (leftvt == VT_UI1 || rightvt == VT_UI1) { if (leftvt == rightvt) resvt = VT_UI1; else if (leftvt == rightvt || leftvt == VT_I2 || rightvt == VT_I2 || leftvt == VT_BOOL || rightvt == VT_BOOL) { resvt = VT_I2; } else if (leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_I8; } else if (leftvt == VT_I2 || rightvt == VT_I2) { if (leftvt == rightvt || leftvt == VT_BOOL || rightvt == VT_BOOL) resvt = VT_I2; else if (leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_I8; } else if (leftvt == VT_BOOL && rightvt == VT_BOOL) { resvt = VT_BOOL; } else if (leftvt == VT_I8 || rightvt == VT_I8) { if (leftvt == VT_INT || rightvt == VT_INT) bFail = TRUE; else resvt = VT_I8; } hres = pVarOr(&left, &right, &result); if (bFail) ok(hres == DISP_E_TYPEMISMATCH || hres == DISP_E_BADVARTYPE, "VarOr: %d|0x%X, %d|0x%X: Expected failure, got 0x%lX vt %d\n", leftvt, ExtraFlags[i], rightvt, ExtraFlags[i], hres, V_VT(&result)); else ok(hres == S_OK && V_VT(&result) == resvt, "VarOr: %d|0x%X, %d|0x%X: expected S_OK, vt %d, got 0x%lX vt %d\n", leftvt, ExtraFlags[i], rightvt, ExtraFlags[i], resvt, hres, V_VT(&result)); } } } /* Test returned values. Since we know the returned type is correct * and that we handle all combinations of invalid types, just check * that good type combinations produce the desired value. * FIXME: Test VT_DECIMAL/VT_DISPATCH */ VAROR(EMPTY,0,EMPTY,0,I2,0); VAROR(EMPTY,1,EMPTY,0,I2,0); VAROR(EMPTY,0,NULL,0,NULL,0); VAROR(EMPTY,0,I1,0,I4,0); VAROR(EMPTY,0,I1,1,I4,1); VAROR(EMPTY,0,UI1,0,I2,0); VAROR(EMPTY,0,UI1,1,I2,1); VAROR(EMPTY,0,I2,0,I2,0); VAROR(EMPTY,0,I2,1,I2,1); VAROR(EMPTY,0,UI2,0,I4,0); VAROR(EMPTY,0,UI2,1,I4,1); VAROR(EMPTY,0,I4,0,I4,0); VAROR(EMPTY,0,I4,1,I4,1); VAROR(EMPTY,0,UI4,0,I4,0); VAROR(EMPTY,0,UI4,1,I4,1); if (HAVE_OLEAUT32_I8) { VAROR(EMPTY,0,I8,0,I8,0); VAROR(EMPTY,0,I8,1,I8,1); VAROR(EMPTY,0,UI8,0,I4,0); VAROR(EMPTY,0,UI8,1,I4,1); } VAROR(EMPTY,0,INT,0,I4,0); VAROR(EMPTY,0,INT,1,I4,1); VAROR(EMPTY,0,UINT,0,I4,0); VAROR(EMPTY,0,UINT,1,I4,1); VAROR(EMPTY,0,BOOL,0,I2,0); VAROR(EMPTY,0,BOOL,1,I2,1); VAROR(EMPTY,0,R4,0,I4,0); VAROR(EMPTY,0,R4,1,I4,1); VAROR(EMPTY,0,R8,0,I4,0); VAROR(EMPTY,0,R8,1,I4,1); rbstr = SysAllocString(szFalse); VAROR(EMPTY,0,BSTR,rbstr,I2,0); rbstr = SysAllocString(szTrue); VAROR(EMPTY,0,BSTR,rbstr,I2,-1); VARORCY(EMPTY,0,10000,I4,1); /* NULL OR 0 = NULL. NULL OR n = n */ VAROR(NULL,0,NULL,0,NULL,0); VAROR(NULL,1,NULL,0,NULL,0); VAROR(NULL,0,I1,0,NULL,0); VAROR(NULL,0,I1,1,I4,1); VAROR(NULL,0,UI1,0,NULL,0); VAROR(NULL,0,UI1,1,UI1,1); VAROR(NULL,0,I2,0,NULL,0); VAROR(NULL,0,I2,1,I2,1); VAROR(NULL,0,UI2,0,NULL,0); VAROR(NULL,0,UI2,1,I4,1); VAROR(NULL,0,I4,0,NULL,0); VAROR(NULL,0,I4,1,I4,1); VAROR(NULL,0,UI4,0,NULL,0); VAROR(NULL,0,UI4,1,I4,1); if (HAVE_OLEAUT32_I8) { VAROR(NULL,0,I8,0,NULL,0); VAROR(NULL,0,I8,1,I8,1); VAROR(NULL,0,UI8,0,NULL,0); VAROR(NULL,0,UI8,1,I4,1); } VAROR(NULL,0,INT,0,NULL,0); VAROR(NULL,0,INT,1,I4,1); VAROR(NULL,0,UINT,0,NULL,0); VAROR(NULL,0,UINT,1,I4,1); VAROR(NULL,0,BOOL,0,NULL,0); VAROR(NULL,0,BOOL,1,BOOL,1); VAROR(NULL,0,R4,0,NULL,0); VAROR(NULL,0,R4,1,I4,1); VAROR(NULL,0,R8,0,NULL,0); VAROR(NULL,0,R8,1,I4,1); rbstr = SysAllocString(szFalse); VAROR(NULL,0,BSTR,rbstr,NULL,0); rbstr = SysAllocString(szTrue); VAROR(NULL,0,BSTR,rbstr,BOOL,VARIANT_TRUE); VARORCY(NULL,0,10000,I4,1); VARORCY(NULL,0,0,NULL,0); VAROR(BOOL,VARIANT_TRUE,BOOL,VARIANT_TRUE,BOOL,VARIANT_TRUE); VAROR(BOOL,VARIANT_TRUE,BOOL,VARIANT_FALSE,BOOL,VARIANT_TRUE); VAROR(BOOL,VARIANT_FALSE,BOOL,VARIANT_TRUE,BOOL,VARIANT_TRUE); VAROR(BOOL,VARIANT_FALSE,BOOL,VARIANT_FALSE,BOOL,VARIANT_FALSE); /* Assume x,y & y,x are the same from now on to reduce the number of tests */ VAROR(BOOL,VARIANT_TRUE,I1,-1,I4,-1); VAROR(BOOL,VARIANT_TRUE,I1,0,I4,-1); VAROR(BOOL,VARIANT_FALSE,I1,0,I4,0); VAROR(BOOL,VARIANT_TRUE,UI1,255,I2,-1); VAROR(BOOL,VARIANT_TRUE,UI1,0,I2,-1); VAROR(BOOL,VARIANT_FALSE,UI1,0,I2,0); VAROR(BOOL,VARIANT_TRUE,I2,-1,I2,-1); VAROR(BOOL,VARIANT_TRUE,I2,0,I2,-1); VAROR(BOOL,VARIANT_FALSE,I2,0,I2,0); VAROR(BOOL,VARIANT_TRUE,UI2,65535,I4,-1); VAROR(BOOL,VARIANT_TRUE,UI2,0,I4,-1); VAROR(BOOL,VARIANT_FALSE,UI2,0,I4,0); VAROR(BOOL,VARIANT_TRUE,I4,-1,I4,-1); VAROR(BOOL,VARIANT_TRUE,I4,0,I4,-1); VAROR(BOOL,VARIANT_FALSE,I4,0,I4,0); VAROR(BOOL,VARIANT_TRUE,UI4,0xffffffff,I4,-1); VAROR(BOOL,VARIANT_TRUE,UI4,0,I4,-1); VAROR(BOOL,VARIANT_FALSE,UI4,0,I4,0); VAROR(BOOL,VARIANT_TRUE,R4,-1,I4,-1); VAROR(BOOL,VARIANT_TRUE,R4,0,I4,-1); VAROR(BOOL,VARIANT_FALSE,R4,0,I4,0); VAROR(BOOL,VARIANT_TRUE,R8,-1,I4,-1); VAROR(BOOL,VARIANT_TRUE,R8,0,I4,-1); VAROR(BOOL,VARIANT_FALSE,R8,0,I4,0); VAROR(BOOL,VARIANT_TRUE,DATE,-1,I4,-1); VAROR(BOOL,VARIANT_TRUE,DATE,0,I4,-1); VAROR(BOOL,VARIANT_FALSE,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VAROR(BOOL,VARIANT_TRUE,I8,-1,I8,-1); VAROR(BOOL,VARIANT_TRUE,I8,0,I8,-1); VAROR(BOOL,VARIANT_FALSE,I8,0,I8,0); /* This returns DISP_E_OVERFLOW which indicates that a conversion * to I4 is performed. */ /* VAROR(BOOL,VARIANT_TRUE,UI8,-1,I4,-1); */ VAROR(BOOL,VARIANT_TRUE,UI8,0,I4,-1); VAROR(BOOL,VARIANT_FALSE,UI8,0,I4,0); } VAROR(BOOL,VARIANT_TRUE,INT,-1,I4,-1); VAROR(BOOL,VARIANT_TRUE,INT,0,I4,-1); VAROR(BOOL,VARIANT_FALSE,INT,0,I4,0); VAROR(BOOL,VARIANT_TRUE,UINT,0xffffffff,I4,-1); VAROR(BOOL,VARIANT_TRUE,UINT,0,I4,-1); VAROR(BOOL,VARIANT_FALSE,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(BOOL,VARIANT_FALSE,BSTR,rbstr,BOOL,VARIANT_FALSE); VAROR(BOOL,VARIANT_TRUE,BSTR,rbstr,BOOL,VARIANT_TRUE); rbstr = SysAllocString(szTrue); VAROR(BOOL,VARIANT_FALSE,BSTR,rbstr,BOOL,VARIANT_TRUE); VAROR(BOOL,VARIANT_TRUE,BSTR,rbstr,BOOL,VARIANT_TRUE); VARORCY(BOOL,VARIANT_TRUE,10000,I4,-1); VARORCY(BOOL,VARIANT_TRUE,0,I4,-1); VARORCY(BOOL,VARIANT_FALSE,0,I4,0); VAROR(I1,-1,I1,-1,I4,-1); VAROR(I1,-1,I1,0,I4,-1); VAROR(I1,0,I1,0,I4,0); VAROR(I1,-1,UI1,255,I4,-1); VAROR(I1,-1,UI1,0,I4,-1); VAROR(I1,0,UI1,0,I4,0); VAROR(I1,-1,I2,-1,I4,-1); VAROR(I1,-1,I2,0,I4,-1); VAROR(I1,0,I2,0,I4,0); VAROR(I1,-1,UI2,65535,I4,-1); VAROR(I1,-1,UI2,0,I4,-1); VAROR(I1,0,UI2,0,I4,0); VAROR(I1,-1,I4,-1,I4,-1); VAROR(I1,-1,I4,0,I4,-1); VAROR(I1,0,I4,0,I4,0); VAROR(I1,-1,UI4,0xffffffff,I4,-1); VAROR(I1,-1,UI4,0,I4,-1); VAROR(I1,0,UI4,0,I4,0); VAROR(I1,-1,R4,-1,I4,-1); VAROR(I1,-1,R4,0,I4,-1); VAROR(I1,0,R4,0,I4,0); VAROR(I1,-1,R8,-1,I4,-1); VAROR(I1,-1,R8,0,I4,-1); VAROR(I1,0,R8,0,I4,0); VAROR(I1,-1,DATE,-1,I4,-1); VAROR(I1,-1,DATE,0,I4,-1); VAROR(I1,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VAROR(I1,-1,I8,-1,I8,-1); VAROR(I1,-1,I8,0,I8,-1); VAROR(I1,0,I8,0,I8,0); VAROR(I1,-1,UI8,0,I4,-1); VAROR(I1,0,UI8,0,I4,0); } VAROR(I1,-1,INT,-1,I4,-1); VAROR(I1,-1,INT,0,I4,-1); VAROR(I1,0,INT,0,I4,0); VAROR(I1,-1,UINT,0xffffffff,I4,-1); VAROR(I1,-1,UINT,0,I4,-1); VAROR(I1,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(I1,0,BSTR,rbstr,I4,0); VAROR(I1,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VAROR(I1,0,BSTR,rbstr,I4,-1); VAROR(I1,-1,BSTR,rbstr,I4,-1); VARORCY(I1,-1,10000,I4,-1); VARORCY(I1,-1,0,I4,-1); VARORCY(I1,0,0,I4,0); VAROR(UI1,255,UI1,255,UI1,255); VAROR(UI1,255,UI1,0,UI1,255); VAROR(UI1,0,UI1,0,UI1,0); VAROR(UI1,255,I2,-1,I2,-1); VAROR(UI1,255,I2,0,I2,255); VAROR(UI1,0,I2,0,I2,0); VAROR(UI1,255,UI2,65535,I4,65535); VAROR(UI1,255,UI2,0,I4,255); VAROR(UI1,0,UI2,0,I4,0); VAROR(UI1,255,I4,-1,I4,-1); VAROR(UI1,255,I4,0,I4,255); VAROR(UI1,0,I4,0,I4,0); VAROR(UI1,255,UI4,0xffffffff,I4,-1); VAROR(UI1,255,UI4,0,I4,255); VAROR(UI1,0,UI4,0,I4,0); VAROR(UI1,255,R4,-1,I4,-1); VAROR(UI1,255,R4,0,I4,255); VAROR(UI1,0,R4,0,I4,0); VAROR(UI1,255,R8,-1,I4,-1); VAROR(UI1,255,R8,0,I4,255); VAROR(UI1,0,R8,0,I4,0); VAROR(UI1,255,DATE,-1,I4,-1); VAROR(UI1,255,DATE,0,I4,255); VAROR(UI1,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VAROR(UI1,255,I8,-1,I8,-1); VAROR(UI1,255,I8,0,I8,255); VAROR(UI1,0,I8,0,I8,0); VAROR(UI1,255,UI8,0,I4,255); VAROR(UI1,0,UI8,0,I4,0); } VAROR(UI1,255,INT,-1,I4,-1); VAROR(UI1,255,INT,0,I4,255); VAROR(UI1,0,INT,0,I4,0); VAROR(UI1,255,UINT,0xffffffff,I4,-1); VAROR(UI1,255,UINT,0,I4,255); VAROR(UI1,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(UI1,0,BSTR,rbstr,I2,0); VAROR(UI1,255,BSTR,rbstr,I2,255); rbstr = SysAllocString(szTrue); VAROR(UI1,0,BSTR,rbstr,I2,-1); VAROR(UI1,255,BSTR,rbstr,I2,-1); VARORCY(UI1,255,10000,I4,255); VARORCY(UI1,255,0,I4,255); VARORCY(UI1,0,0,I4,0); VAROR(I2,-1,I2,-1,I2,-1); VAROR(I2,-1,I2,0,I2,-1); VAROR(I2,0,I2,0,I2,0); VAROR(I2,-1,UI2,65535,I4,-1); VAROR(I2,-1,UI2,0,I4,-1); VAROR(I2,0,UI2,0,I4,0); VAROR(I2,-1,I4,-1,I4,-1); VAROR(I2,-1,I4,0,I4,-1); VAROR(I2,0,I4,0,I4,0); VAROR(I2,-1,UI4,0xffffffff,I4,-1); VAROR(I2,-1,UI4,0,I4,-1); VAROR(I2,0,UI4,0,I4,0); VAROR(I2,-1,R4,-1,I4,-1); VAROR(I2,-1,R4,0,I4,-1); VAROR(I2,0,R4,0,I4,0); VAROR(I2,-1,R8,-1,I4,-1); VAROR(I2,-1,R8,0,I4,-1); VAROR(I2,0,R8,0,I4,0); VAROR(I2,-1,DATE,-1,I4,-1); VAROR(I2,-1,DATE,0,I4,-1); VAROR(I2,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VAROR(I2,-1,I8,-1,I8,-1); VAROR(I2,-1,I8,0,I8,-1); VAROR(I2,0,I8,0,I8,0); VAROR(I2,-1,UI8,0,I4,-1); VAROR(I2,0,UI8,0,I4,0); } VAROR(I2,-1,INT,-1,I4,-1); VAROR(I2,-1,INT,0,I4,-1); VAROR(I2,0,INT,0,I4,0); VAROR(I2,-1,UINT,0xffffffff,I4,-1); VAROR(I2,-1,UINT,0,I4,-1); VAROR(I2,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(I2,0,BSTR,rbstr,I2,0); VAROR(I2,-1,BSTR,rbstr,I2,-1); rbstr = SysAllocString(szTrue); VAROR(I2,0,BSTR,rbstr,I2,-1); VAROR(I2,-1,BSTR,rbstr,I2,-1); VARORCY(I2,-1,10000,I4,-1); VARORCY(I2,-1,0,I4,-1); VARORCY(I2,0,0,I4,0); VAROR(UI2,65535,UI2,65535,I4,65535); VAROR(UI2,65535,UI2,0,I4,65535); VAROR(UI2,0,UI2,0,I4,0); VAROR(UI2,65535,I4,-1,I4,-1); VAROR(UI2,65535,I4,0,I4,65535); VAROR(UI2,0,I4,0,I4,0); VAROR(UI2,65535,UI4,0xffffffff,I4,-1); VAROR(UI2,65535,UI4,0,I4,65535); VAROR(UI2,0,UI4,0,I4,0); VAROR(UI2,65535,R4,-1,I4,-1); VAROR(UI2,65535,R4,0,I4,65535); VAROR(UI2,0,R4,0,I4,0); VAROR(UI2,65535,R8,-1,I4,-1); VAROR(UI2,65535,R8,0,I4,65535); VAROR(UI2,0,R8,0,I4,0); VAROR(UI2,65535,DATE,-1,I4,-1); VAROR(UI2,65535,DATE,0,I4,65535); VAROR(UI2,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VAROR(UI2,65535,I8,-1,I8,-1); VAROR(UI2,65535,I8,0,I8,65535); VAROR(UI2,0,I8,0,I8,0); VAROR(UI2,65535,UI8,0,I4,65535); VAROR(UI2,0,UI8,0,I4,0); } VAROR(UI2,65535,INT,-1,I4,-1); VAROR(UI2,65535,INT,0,I4,65535); VAROR(UI2,0,INT,0,I4,0); VAROR(UI2,65535,UINT,0xffffffff,I4,-1); VAROR(UI2,65535,UINT,0,I4,65535); VAROR(UI2,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(UI2,0,BSTR,rbstr,I4,0); VAROR(UI2,65535,BSTR,rbstr,I4,65535); rbstr = SysAllocString(szTrue); VAROR(UI2,0,BSTR,rbstr,I4,-1); VAROR(UI2,65535,BSTR,rbstr,I4,-1); VARORCY(UI2,65535,10000,I4,65535); VARORCY(UI2,65535,0,I4,65535); VARORCY(UI2,0,0,I4,0); VAROR(I4,-1,I4,-1,I4,-1); VAROR(I4,-1,I4,0,I4,-1); VAROR(I4,0,I4,0,I4,0); VAROR(I4,-1,UI4,0xffffffff,I4,-1); VAROR(I4,-1,UI4,0,I4,-1); VAROR(I4,0,UI4,0,I4,0); VAROR(I4,-1,R4,-1,I4,-1); VAROR(I4,-1,R4,0,I4,-1); VAROR(I4,0,R4,0,I4,0); VAROR(I4,-1,R8,-1,I4,-1); VAROR(I4,-1,R8,0,I4,-1); VAROR(I4,0,R8,0,I4,0); VAROR(I4,-1,DATE,-1,I4,-1); VAROR(I4,-1,DATE,0,I4,-1); VAROR(I4,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VAROR(I4,-1,I8,-1,I8,-1); VAROR(I4,-1,I8,0,I8,-1); VAROR(I4,0,I8,0,I8,0); VAROR(I4,-1,UI8,0,I4,-1); VAROR(I4,0,UI8,0,I4,0); } VAROR(I4,-1,INT,-1,I4,-1); VAROR(I4,-1,INT,0,I4,-1); VAROR(I4,0,INT,0,I4,0); VAROR(I4,-1,UINT,0xffffffff,I4,-1); VAROR(I4,-1,UINT,0,I4,-1); VAROR(I4,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(I4,0,BSTR,rbstr,I4,0); VAROR(I4,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VAROR(I4,0,BSTR,rbstr,I4,-1); VAROR(I4,-1,BSTR,rbstr,I4,-1); VARORCY(I4,-1,10000,I4,-1); VARORCY(I4,-1,0,I4,-1); VARORCY(I4,0,0,I4,0); VAROR(UI4,0xffffffff,UI4,0xffffffff,I4,-1); VAROR(UI4,0xffffffff,UI4,0,I4,-1); VAROR(UI4,0,UI4,0,I4,0); VAROR(UI4,0xffffffff,R4,-1,I4,-1); VAROR(UI4,0xffffffff,R4,0,I4,-1); VAROR(UI4,0,R4,0,I4,0); VAROR(UI4,0xffffffff,R8,-1,I4,-1); VAROR(UI4,0xffffffff,R8,0,I4,-1); VAROR(UI4,0,R8,0,I4,0); VAROR(UI4,0xffffffff,DATE,-1,I4,-1); VAROR(UI4,0xffffffff,DATE,0,I4,-1); VAROR(UI4,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VAROR(UI4,0xffffffff,I8,-1,I8,-1); VAROR(UI4,0xffffffff,I8,0,I8,0xffffffff); VAROR(UI4,0,I8,0,I8,0); VAROR(UI4,0xffffffff,UI8,0,I4,-1); VAROR(UI4,0,UI8,0,I4,0); } VAROR(UI4,0xffffffff,INT,-1,I4,-1); VAROR(UI4,0xffffffff,INT,0,I4,-1); VAROR(UI4,0,INT,0,I4,0); VAROR(UI4,0xffffffff,UINT,0xffffffff,I4,-1); VAROR(UI4,0xffffffff,UINT,0,I4,-1); VAROR(UI4,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(UI4,0,BSTR,rbstr,I4,0); VAROR(UI4,0xffffffff,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VAROR(UI4,0,BSTR,rbstr,I4,-1); VAROR(UI4,0xffffffff,BSTR,rbstr,I4,-1); VARORCY(UI4,0xffffffff,10000,I4,-1); VARORCY(UI4,0xffffffff,0,I4,-1); VARORCY(UI4,0,0,I4,0); VAROR(R4,-1,R4,-1,I4,-1); VAROR(R4,-1,R4,0,I4,-1); VAROR(R4,0,R4,0,I4,0); VAROR(R4,-1,R8,-1,I4,-1); VAROR(R4,-1,R8,0,I4,-1); VAROR(R4,0,R8,0,I4,0); VAROR(R4,-1,DATE,-1,I4,-1); VAROR(R4,-1,DATE,0,I4,-1); VAROR(R4,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VAROR(R4,-1,I8,-1,I8,-1); VAROR(R4,-1,I8,0,I8,-1); VAROR(R4,0,I8,0,I8,0); VAROR(R4,-1,UI8,0,I4,-1); VAROR(R4,0,UI8,0,I4,0); } VAROR(R4,-1,INT,-1,I4,-1); VAROR(R4,-1,INT,0,I4,-1); VAROR(R4,0,INT,0,I4,0); VAROR(R4,-1,UINT,0xffffffff,I4,-1); VAROR(R4,-1,UINT,0,I4,-1); VAROR(R4,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(R4,0,BSTR,rbstr,I4,0); VAROR(R4,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VAROR(R4,0,BSTR,rbstr,I4,-1); VAROR(R4,-1,BSTR,rbstr,I4,-1); VARORCY(R4,-1,10000,I4,-1); VARORCY(R4,-1,0,I4,-1); VARORCY(R4,0,0,I4,0); VAROR(R8,-1,R8,-1,I4,-1); VAROR(R8,-1,R8,0,I4,-1); VAROR(R8,0,R8,0,I4,0); VAROR(R8,-1,DATE,-1,I4,-1); VAROR(R8,-1,DATE,0,I4,-1); VAROR(R8,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VAROR(R8,-1,I8,-1,I8,-1); VAROR(R8,-1,I8,0,I8,-1); VAROR(R8,0,I8,0,I8,0); VAROR(R8,-1,UI8,0,I4,-1); VAROR(R8,0,UI8,0,I4,0); } VAROR(R8,-1,INT,-1,I4,-1); VAROR(R8,-1,INT,0,I4,-1); VAROR(R8,0,INT,0,I4,0); VAROR(R8,-1,UINT,0xffffffff,I4,-1); VAROR(R8,-1,UINT,0,I4,-1); VAROR(R8,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(R8,0,BSTR,rbstr,I4,0); VAROR(R8,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VAROR(R8,0,BSTR,rbstr,I4,-1); VAROR(R8,-1,BSTR,rbstr,I4,-1); VARORCY(R8,-1,10000,I4,-1); VARORCY(R8,-1,0,I4,-1); VARORCY(R8,0,0,I4,0); VAROR(DATE,-1,DATE,-1,I4,-1); VAROR(DATE,-1,DATE,0,I4,-1); VAROR(DATE,0,DATE,0,I4,0); if (HAVE_OLEAUT32_I8) { VAROR(DATE,-1,I8,-1,I8,-1); VAROR(DATE,-1,I8,0,I8,-1); VAROR(DATE,0,I8,0,I8,0); VAROR(DATE,-1,UI8,0,I4,-1); VAROR(DATE,0,UI8,0,I4,0); } VAROR(DATE,-1,INT,-1,I4,-1); VAROR(DATE,-1,INT,0,I4,-1); VAROR(DATE,0,INT,0,I4,0); VAROR(DATE,-1,UINT,0xffffffff,I4,-1); VAROR(DATE,-1,UINT,0,I4,-1); VAROR(DATE,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(DATE,0,BSTR,rbstr,I4,0); VAROR(DATE,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VAROR(DATE,0,BSTR,rbstr,I4,-1); VAROR(DATE,-1,BSTR,rbstr,I4,-1); VARORCY(DATE,-1,10000,I4,-1); VARORCY(DATE,-1,0,I4,-1); VARORCY(DATE,0,0,I4,0); if (HAVE_OLEAUT32_I8) { VAROR(I8,-1,I8,-1,I8,-1); VAROR(I8,-1,I8,0,I8,-1); VAROR(I8,0,I8,0,I8,0); VAROR(I8,-1,UI8,0,I8,-1); VAROR(I8,0,UI8,0,I8,0); /* These overflow under native and Wine VAROR(I8,-1,INT,-1,I4,-1); VAROR(I8,-1,INT,0,I4,-1); VAROR(I8,0,INT,0,I4,0); */ VAROR(I8,-1,UINT,0xffffffff,I8,-1); VAROR(I8,-1,UINT,0,I8,-1); VAROR(I8,0,UINT,0,I8,0); rbstr = SysAllocString(szFalse); VAROR(I8,0,BSTR,rbstr,I8,0); VAROR(I8,-1,BSTR,rbstr,I8,-1); rbstr = SysAllocString(szTrue); VAROR(I8,0,BSTR,rbstr,I8,-1); VAROR(I8,-1,BSTR,rbstr,I8,-1); VARORCY(I8,-1,10000,I8,-1); VARORCY(I8,-1,0,I8,-1); VARORCY(I8,0,0,I8,0); VAROR(UI8,0xffff,UI8,0xffff,I4,0xffff); VAROR(UI8,0xffff,UI8,0,I4,0xffff); VAROR(UI8,0,UI8,0,I4,0); VAROR(UI8,0xffff,INT,-1,I4,-1); VAROR(UI8,0xffff,INT,0,I4,0xffff); VAROR(UI8,0,INT,0,I4,0); VAROR(UI8,0xffff,UINT,0xffff,I4,0xffff); VAROR(UI8,0xffff,UINT,0,I4,0xffff); VAROR(UI8,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(UI8,0,BSTR,rbstr,I4,0); VAROR(UI8,0xffff,BSTR,rbstr,I4,0xffff); rbstr = SysAllocString(szTrue); VAROR(UI8,0,BSTR,rbstr,I4,-1); VAROR(UI8,0xffff,BSTR,rbstr,I4,-1); VARORCY(UI8,0xffff,10000,I4,0xffff); VARORCY(UI8,0xffff,0,I4,0xffff); VARORCY(UI8,0,0,I4,0); } VAROR(INT,-1,INT,-1,I4,-1); VAROR(INT,-1,INT,0,I4,-1); VAROR(INT,0,INT,0,I4,0); VAROR(INT,-1,UINT,0xffff,I4,-1); VAROR(INT,-1,UINT,0,I4,-1); VAROR(INT,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(INT,0,BSTR,rbstr,I4,0); VAROR(INT,-1,BSTR,rbstr,I4,-1); rbstr = SysAllocString(szTrue); VAROR(INT,0,BSTR,rbstr,I4,-1); VAROR(INT,-1,BSTR,rbstr,I4,-1); VARORCY(INT,-1,10000,I4,-1); VARORCY(INT,-1,0,I4,-1); VARORCY(INT,0,0,I4,0); VAROR(UINT,0xffff,UINT,0xffff,I4,0xffff); VAROR(UINT,0xffff,UINT,0,I4,0xffff); VAROR(UINT,0,UINT,0,I4,0); rbstr = SysAllocString(szFalse); VAROR(UINT,0,BSTR,rbstr,I4,0); VAROR(UINT,0xffff,BSTR,rbstr,I4,0xffff); rbstr = SysAllocString(szTrue); VAROR(UINT,0,BSTR,rbstr,I4,-1); VAROR(UINT,0xffff,BSTR,rbstr,I4,-1); VARORCY(UINT,0xffff,10000,I4,0xffff); VARORCY(UINT,0xffff,0,I4,0xffff); VARORCY(UINT,0,0,I4,0); lbstr = SysAllocString(szFalse); rbstr = SysAllocString(szFalse); VAROR(BSTR,lbstr,BSTR,rbstr,BOOL,0); rbstr = SysAllocString(szTrue); VAROR(BSTR,lbstr,BSTR,rbstr,BOOL,VARIANT_TRUE); lbstr = SysAllocString(szTrue); VAROR(BSTR,lbstr,BSTR,rbstr,BOOL,VARIANT_TRUE); VARORCY(BSTR,lbstr,10000,I4,-1); lbstr = SysAllocString(szFalse); VARORCY(BSTR,lbstr,10000,I4,1); } static HRESULT (WINAPI *pVarEqv)(LPVARIANT,LPVARIANT,LPVARIANT); static const char *szVarEqvFail = "VarEqv(%d,%d): expected 0x0,%d,%d, got 0x%lX,%d,%d\n"; #define VAREQV(vt1,val1,vt2,val2,rvt,rval) \ V_VT(&left) = VT_##vt1; V_##vt1(&left) = val1; \ V_VT(&right) = VT_##vt2; V_##vt2(&right) = val2; \ memset(&result,0,sizeof(result)); hres = pVarEqv(&left,&right,&result); \ ok(hres == S_OK && V_VT(&result) == VT_##rvt && V_##rvt(&result) == (rval), \ szVarEqvFail, VT_##vt1, VT_##vt2, \ VT_##rvt, (int)(rval), hres, V_VT(&result), (int)V_##rvt(&result)) static void test_VarEqv(void) { VARIANT left, right, result; VARTYPE i; HRESULT hres; CHECKPTR(VarEqv); /* Test all possible flag/vt combinations & the resulting vt type */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]); i++) { VARTYPE leftvt, rightvt, resvt; for (leftvt = 0; leftvt <= VT_BSTR_BLOB; leftvt++) { SKIPTESTS(leftvt); for (rightvt = 0; rightvt <= VT_BSTR_BLOB; rightvt++) { BOOL bFail = FALSE; SKIPTESTS(rightvt); if (leftvt == VT_BSTR || rightvt == VT_BSTR || leftvt == VT_DISPATCH || rightvt == VT_DISPATCH || leftvt == VT_UNKNOWN || rightvt == VT_UNKNOWN) continue; memset(&left, 0, sizeof(left)); memset(&right, 0, sizeof(right)); V_VT(&left) = leftvt | ExtraFlags[i]; V_VT(&right) = rightvt | ExtraFlags[i]; V_VT(&result) = VT_EMPTY; resvt = VT_I4; if (ExtraFlags[i] & VT_ARRAY || ExtraFlags[i] & VT_BYREF || !IsValidVariantClearVT(leftvt, ExtraFlags[i]) || !IsValidVariantClearVT(rightvt, ExtraFlags[i]) || leftvt == VT_CLSID || rightvt == VT_CLSID || leftvt == VT_RECORD || rightvt == VT_RECORD || leftvt == VT_VARIANT || rightvt == VT_VARIANT || leftvt == VT_ERROR || rightvt == VT_ERROR) { bFail = TRUE; } if (leftvt == VT_EMPTY || rightvt == VT_EMPTY) { if (leftvt == rightvt || leftvt == VT_I2 || rightvt == VT_I2 || leftvt == VT_UI1 || rightvt == VT_UI1 || leftvt == VT_BOOL || rightvt == VT_BOOL) resvt = VT_I2; else if (leftvt == VT_NULL || rightvt == VT_NULL) resvt = VT_NULL; else if (leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_I8; } else if (leftvt == VT_NULL || rightvt == VT_NULL) { resvt = VT_NULL; } else if (leftvt == VT_UI1 || rightvt == VT_UI1) { if (leftvt == rightvt) resvt = VT_UI1; else if (leftvt == rightvt || leftvt == VT_I2 || rightvt == VT_I2 || leftvt == VT_BOOL || rightvt == VT_BOOL) { resvt = VT_I2; } else if (leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_I8; } else if (leftvt == VT_I2 || rightvt == VT_I2) { if (leftvt == rightvt || leftvt == VT_BOOL || rightvt == VT_BOOL) resvt = VT_I2; else if (leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_I8; } else if (leftvt == VT_BOOL && rightvt == VT_BOOL) { resvt = VT_BOOL; } else if (leftvt == VT_I8 || rightvt == VT_I8) { if (leftvt == VT_INT || rightvt == VT_INT) bFail = TRUE; else resvt = VT_I8; } hres = pVarEqv(&left, &right, &result); if (bFail) ok(hres == DISP_E_TYPEMISMATCH || hres == DISP_E_BADVARTYPE, "VarEqv: %d|0x%X, %d|0x%X: Expected failure, got 0x%lX vt %d\n", leftvt, ExtraFlags[i], rightvt, ExtraFlags[i], hres, V_VT(&result)); else ok(hres == S_OK && V_VT(&result) == resvt, "VarEqv: %d|0x%X, %d|0x%X: expected S_OK, vt %d, got 0x%lX vt %d\n", leftvt, ExtraFlags[i], rightvt, ExtraFlags[i], resvt, hres, V_VT(&result)); } } } /* Test returned values */ VAREQV(BOOL,VARIANT_TRUE,BOOL,VARIANT_TRUE,BOOL,VARIANT_TRUE); VAREQV(BOOL,VARIANT_FALSE,BOOL,VARIANT_TRUE,BOOL,VARIANT_FALSE); VAREQV(BOOL,TRUE,BOOL,TRUE,BOOL,VARIANT_TRUE); VAREQV(BOOL,FALSE,BOOL,FALSE,BOOL,VARIANT_TRUE); VAREQV(BOOL,TRUE,BOOL,FALSE,BOOL,-2); VAREQV(BOOL,FALSE,BOOL,TRUE,BOOL,-2); VAREQV(BOOL,6,BOOL,7,BOOL,-2); VAREQV(BOOL,6,BOOL,6,BOOL,VARIANT_TRUE); VAREQV(BOOL,VARIANT_TRUE,I2,VARIANT_TRUE,I2,VARIANT_TRUE); VAREQV(BOOL,VARIANT_TRUE,I2,VARIANT_FALSE,I2,VARIANT_FALSE); VAREQV(BOOL,6,I2,7,I2,-2); VAREQV(UI1,1,UI1,1,UI1,255); VAREQV(UI1,1,UI1,0,UI1,254); VAREQV(UI1,0,UI1,1,UI1,254); if (HAVE_OLEAUT32_I8) { VAREQV(UI4,VARIANT_FALSE,I8,VARIANT_FALSE,I8,-1); VAREQV(UI4,5,I8,19,I8,-23); VAREQV(UI4,VARIANT_FALSE,UI8,VARIANT_FALSE,I4,-1); } } static HRESULT (WINAPI *pVarMul)(LPVARIANT,LPVARIANT,LPVARIANT); static const char *szVarMulI4 = "VarMul(%d,%d): expected 0x0,%d,%d, got 0x%lX,%d,%d\n"; static const char *szVarMulR8 = "VarMul(%d,%d): expected 0x0,%d,%f, got 0x%lX,%d,%f\n"; #define VARMUL(vt1,val1,vt2,val2,rvt,rval) \ V_VT(&left) = VT_##vt1; V_##vt1(&left) = val1; \ V_VT(&right) = VT_##vt2; V_##vt2(&right) = val2; \ memset(&result,0,sizeof(result)); hres = pVarMul(&left,&right,&result); \ if (VT_##rvt == VT_R4 || VT_##rvt == VT_R8) { \ ok(hres == S_OK && V_VT(&result) == VT_##rvt && \ EQ_FLOAT(V_##rvt(&result), rval), \ szVarMulR8, VT_##vt1, VT_##vt2, \ VT_##rvt, (double)(rval), hres, V_VT(&result), (double)V_##rvt(&result)); \ } else { \ ok(hres == S_OK && V_VT(&result) == VT_##rvt && V_##rvt(&result) == (rval), \ szVarMulI4, VT_##vt1, VT_##vt2, \ VT_##rvt, (int)(rval), hres, V_VT(&result), (int)V_##rvt(&result)); } static void test_VarMul(void) { static const WCHAR sz12[] = {'1','2','\0'}; VARIANT left, right, result, cy, dec; VARTYPE i; BSTR lbstr, rbstr; HRESULT hres; double r; CHECKPTR(VarMul); lbstr = SysAllocString(sz12); rbstr = SysAllocString(sz12); /* Test all possible flag/vt combinations & the resulting vt type */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]); i++) { VARTYPE leftvt, rightvt, resvt; for (leftvt = 0; leftvt <= VT_BSTR_BLOB; leftvt++) { SKIPTESTS(leftvt); for (rightvt = 0; rightvt <= VT_BSTR_BLOB; rightvt++) { BOOL bFail = FALSE; SKIPTESTS(rightvt); if (leftvt == VT_DISPATCH || rightvt == VT_DISPATCH || leftvt == VT_UNKNOWN || rightvt == VT_UNKNOWN) continue; memset(&left, 0, sizeof(left)); memset(&right, 0, sizeof(right)); V_VT(&left) = leftvt | ExtraFlags[i]; if (leftvt == VT_BSTR) V_BSTR(&left) = lbstr; V_VT(&right) = rightvt | ExtraFlags[i]; if (rightvt == VT_BSTR) V_BSTR(&right) = rbstr; V_VT(&result) = VT_EMPTY; resvt = VT_UNKNOWN; /* Don't ask me why but native VarMul cannot handle: VT_I1, VT_UI2, VT_UI4, VT_INT, VT_UINT and VT_UI8. Tested with DCOM98, Win2k, WinXP */ if (ExtraFlags[i] & VT_ARRAY || ExtraFlags[i] & VT_BYREF || !IsValidVariantClearVT(leftvt, ExtraFlags[i]) || !IsValidVariantClearVT(rightvt, ExtraFlags[i]) || leftvt == VT_CLSID || rightvt == VT_CLSID || leftvt == VT_RECORD || rightvt == VT_RECORD || leftvt == VT_VARIANT || rightvt == VT_VARIANT || leftvt == VT_ERROR || rightvt == VT_ERROR || leftvt == VT_I1 || rightvt == VT_I1 || leftvt == VT_UI2 || rightvt == VT_UI2 || leftvt == VT_UI4 || rightvt == VT_UI4 || leftvt == VT_UI8 || rightvt == VT_UI8 || leftvt == VT_INT || rightvt == VT_INT || leftvt == VT_UINT || rightvt == VT_UINT) { bFail = TRUE; } if (leftvt == VT_NULL || rightvt == VT_NULL) resvt = VT_NULL; else if (leftvt == VT_DECIMAL || rightvt == VT_DECIMAL) resvt = VT_DECIMAL; else if (leftvt == VT_R8 || rightvt == VT_R8 || leftvt == VT_BSTR || rightvt == VT_BSTR || leftvt == VT_DATE || rightvt == VT_DATE) resvt = VT_R8; else if (leftvt == VT_R4 || rightvt == VT_R4) { if (leftvt == VT_I4 || rightvt == VT_I4 || leftvt == VT_I8 || rightvt == VT_I8 || leftvt == VT_CY || rightvt == VT_CY) resvt = VT_R8; else resvt = VT_R4; } else if (leftvt == VT_CY || rightvt == VT_CY) resvt = VT_CY; else if (leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_I8; else if (leftvt == VT_I4 || rightvt == VT_I4) resvt = VT_I4; else if (leftvt == VT_I2 || rightvt == VT_I2 || leftvt == VT_BOOL || rightvt == VT_BOOL || (leftvt == VT_EMPTY && rightvt == VT_EMPTY)) resvt = VT_I2; else if (leftvt == VT_UI1 || rightvt == VT_UI1) resvt = VT_UI1; hres = pVarMul(&left, &right, &result); if (bFail) { ok(hres == DISP_E_TYPEMISMATCH || hres == DISP_E_BADVARTYPE, "VarMul: %d|0x%X, %d|0x%X: Expected failure, got 0x%lX vt %d\n", leftvt, ExtraFlags[i], rightvt, ExtraFlags[i], hres, V_VT(&result)); } else { ok(hres == S_OK && V_VT(&result) == resvt, "VarMul: %d|0x%X, %d|0x%X: expected S_OK, vt %d, got 0x%lX vt %d\n", leftvt, ExtraFlags[i], rightvt, ExtraFlags[i], resvt, hres, V_VT(&result)); } } } } /* Test returned values */ VARMUL(I4,4,I4,2,I4,8); VARMUL(I2,4,I2,2,I2,8); VARMUL(I2,-13,I4,5,I4,-65); VARMUL(I4,-13,I4,5,I4,-65); VARMUL(I2,7,R4,0.5,R4,3.5); VARMUL(R4,0.5,I4,5,R8,2.5); VARMUL(R8,7.1,BOOL,0,R8,0); VARMUL(BSTR,lbstr,I2,4,R8,48); VARMUL(BSTR,lbstr,BOOL,1,R8,12); VARMUL(BSTR,lbstr,R4,0.1,R8,1.2); VARMUL(BSTR,lbstr,BSTR,rbstr,R8,144); VARMUL(R4,0.2,BSTR,rbstr,R8,2.4); VARMUL(DATE,2.25,I4,7,R8,15.75); VARMUL(UI1, UI1_MAX, UI1, UI1_MAX, I4, UI1_MAX * UI1_MAX); VARMUL(I2, I2_MAX, I2, I2_MAX, I4, I2_MAX * I2_MAX); VARMUL(I2, I2_MAX, I2, I2_MIN, I4, I2_MAX * I2_MIN); VARMUL(I2, I2_MIN, I2, I2_MIN, I4, I2_MIN * I2_MIN); if (HAVE_OLEAUT32_I8) { VARMUL(I4, I4_MAX, I4, I4_MAX, I8, (long long)I4_MAX * I4_MAX); VARMUL(I4, I4_MAX, I4, I4_MIN, I8, (long long)I4_MAX * I4_MIN); VARMUL(I4, I4_MIN, I4, I4_MIN, I8, (long long)I4_MIN * I4_MIN); } else { VARMUL(I4, I4_MAX, I4, I4_MAX, R8, (double)I4_MAX * I4_MAX); VARMUL(I4, I4_MAX, I4, I4_MIN, R8, (double)I4_MAX * I4_MIN); VARMUL(I4, I4_MIN, I4, I4_MIN, R8, (double)I4_MIN * I4_MIN); } VARMUL(R4, R4_MAX, R4, R4_MAX, R8, (double)R4_MAX * R4_MAX); VARMUL(R4, R4_MAX, R4, R4_MIN, R4, R4_MAX * R4_MIN); VARMUL(R4, R4_MIN, R4, R4_MIN, R4, R4_MIN * R4_MIN); VARMUL(R8, R8_MAX, R8, R8_MIN, R8, R8_MAX * R8_MIN); VARMUL(R8, R8_MIN, R8, R8_MIN, R8, R8_MIN * R8_MIN); /* Manuly test some VT_CY and VT_DECIMAL variants */ V_VT(&cy) = VT_CY; hres = VarCyFromI4(4711, &V_CY(&cy)); ok(hres == S_OK, "VarCyFromI4 failed!\n"); V_VT(&dec) = VT_DECIMAL; hres = VarDecFromR8(-4.2, &V_DECIMAL(&dec)); ok(hres == S_OK, "VarDecFromR4 failed!\n"); memset(&left, 0, sizeof(left)); memset(&right, 0, sizeof(right)); V_VT(&left) = VT_I4; V_I4(&left) = -11; V_VT(&right) = VT_UI1; V_UI1(&right) = 9; hres = VarMul(&cy, &right, &result); ok(hres == S_OK && V_VT(&result) == VT_CY, "VarMul: expected coerced type VT_CY, got %s!\n'", vtstr(V_VT(&result))); hres = VarR8FromCy(V_CY(&result), &r); ok(hres == S_OK && EQ_DOUBLE(r, 42399), "VarMul: CY value %f, expected %f\n", r, (double)42399); hres = VarMul(&left, &dec, &result); ok(hres == S_OK && V_VT(&result) == VT_DECIMAL, "VarMul: expected coerced type VT_DECIMAL, got %s!\n'", vtstr(V_VT(&result))); hres = VarR8FromDec(&V_DECIMAL(&result), &r); ok(hres == S_OK && EQ_DOUBLE(r, 46.2), "VarMul: DECIMAL value %f, expected %f\n", r, (double)46.2); } static HRESULT (WINAPI *pVarAdd)(LPVARIANT,LPVARIANT,LPVARIANT); static const char *szVarAddI4 = "VarAdd(%d,%d): expected 0x0,%d,%d, got 0x%lX,%d,%d\n"; static const char *szVarAddR8 = "VarAdd(%d,%d): expected 0x0,%d,%f, got 0x%lX,%d,%f\n"; #define VARADD(vt1,val1,vt2,val2,rvt,rval) \ V_VT(&left) = VT_##vt1; V_##vt1(&left) = val1; \ V_VT(&right) = VT_##vt2; V_##vt2(&right) = val2; \ memset(&result,0,sizeof(result)); hres = pVarAdd(&left,&right,&result); \ if (VT_##rvt == VT_R4 || VT_##rvt == VT_R8 || VT_##rvt == VT_DATE) { \ ok(hres == S_OK && V_VT(&result) == VT_##rvt && \ EQ_FLOAT(V_##rvt(&result), rval), \ szVarAddR8, VT_##vt1, VT_##vt2, \ VT_##rvt, (double)(rval), hres, V_VT(&result), (double)V_##rvt(&result)); \ } else { \ ok(hres == S_OK && V_VT(&result) == VT_##rvt && V_##rvt(&result) == (rval), \ szVarAddI4, VT_##vt1, VT_##vt2, \ VT_##rvt, (int)(rval), hres, V_VT(&result), (int)V_##rvt(&result)); } static void test_VarAdd(void) { static const WCHAR sz12[] = {'1','2','\0'}; VARIANT left, right, result, cy, dec; VARTYPE i; BSTR lbstr, rbstr; HRESULT hres; double r; CHECKPTR(VarAdd); lbstr = SysAllocString(sz12); rbstr = SysAllocString(sz12); /* Test all possible flag/vt combinations & the resulting vt type */ for (i = 0; i < sizeof(ExtraFlags)/sizeof(ExtraFlags[0]); i++) { VARTYPE leftvt, rightvt, resvt; for (leftvt = 0; leftvt <= VT_BSTR_BLOB; leftvt++) { SKIPTESTS(leftvt); for (rightvt = 0; rightvt <= VT_BSTR_BLOB; rightvt++) { BOOL bFail = FALSE; SKIPTESTS(rightvt); if (leftvt == VT_UNKNOWN || rightvt == VT_UNKNOWN) continue; memset(&left, 0, sizeof(left)); memset(&right, 0, sizeof(right)); V_VT(&left) = leftvt | ExtraFlags[i]; if (leftvt == VT_BSTR) V_BSTR(&left) = lbstr; V_VT(&right) = rightvt | ExtraFlags[i]; if (rightvt == VT_BSTR) V_BSTR(&right) = rbstr; V_VT(&result) = VT_EMPTY; resvt = VT_ERROR; /* Don't ask me why but native VarAdd cannot handle: VT_I1, VT_UI2, VT_UI4, VT_INT, VT_UINT and VT_UI8. Tested with DCOM98, Win2k, WinXP */ if (ExtraFlags[i] & VT_ARRAY || ExtraFlags[i] & VT_BYREF || !IsValidVariantClearVT(leftvt, ExtraFlags[i]) || !IsValidVariantClearVT(rightvt, ExtraFlags[i]) || leftvt == VT_CLSID || rightvt == VT_CLSID || leftvt == VT_RECORD || rightvt == VT_RECORD || leftvt == VT_VARIANT || rightvt == VT_VARIANT || leftvt == VT_ERROR || rightvt == VT_ERROR || leftvt == VT_I1 || rightvt == VT_I1 || leftvt == VT_UI2 || rightvt == VT_UI2 || leftvt == VT_UI4 || rightvt == VT_UI4 || leftvt == VT_UI8 || rightvt == VT_UI8 || leftvt == VT_INT || rightvt == VT_INT || leftvt == VT_UINT || rightvt == VT_UINT) { bFail = TRUE; } if (leftvt == VT_NULL || rightvt == VT_NULL) resvt = VT_NULL; else if (leftvt == VT_DISPATCH || rightvt == VT_DISPATCH) bFail = TRUE; else if (leftvt == VT_DECIMAL || rightvt == VT_DECIMAL) resvt = VT_DECIMAL; else if (leftvt == VT_DATE || rightvt == VT_DATE) resvt = VT_DATE; else if (leftvt == VT_CY || rightvt == VT_CY) resvt = VT_CY; else if (leftvt == VT_R8 || rightvt == VT_R8) resvt = VT_R8; else if (leftvt == VT_BSTR || rightvt == VT_BSTR) { if ((leftvt == VT_BSTR && rightvt == VT_BSTR) || leftvt == VT_EMPTY || rightvt == VT_EMPTY) resvt = VT_BSTR; else resvt = VT_R8; } else if (leftvt == VT_R4 || rightvt == VT_R4) { if (leftvt == VT_I4 || rightvt == VT_I4 || leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_R8; else resvt = VT_R4; } else if (leftvt == VT_I8 || rightvt == VT_I8) resvt = VT_I8; else if (leftvt == VT_I4 || rightvt == VT_I4) resvt = VT_I4; else if (leftvt == VT_I2 || rightvt == VT_I2 || leftvt == VT_BOOL || rightvt == VT_BOOL || (leftvt == VT_EMPTY && rightvt == VT_EMPTY)) resvt = VT_I2; else if (leftvt == VT_UI1 || rightvt == VT_UI1) resvt = VT_UI1; hres = pVarAdd(&left, &right, &result); if (bFail) { ok(hres == DISP_E_TYPEMISMATCH || hres == DISP_E_BADVARTYPE, "VarAdd: %d|0x%X, %d|0x%X: Expected failure, got 0x%lX vt %d\n", leftvt, ExtraFlags[i], rightvt, ExtraFlags[i], hres, V_VT(&result)); } else { ok(hres == S_OK && V_VT(&result) == resvt, "VarAdd: %d|0x%X, %d|0x%X: expected S_OK, vt %d, got 0x%lX vt %d\n", leftvt, ExtraFlags[i], rightvt, ExtraFlags[i], resvt, hres, V_VT(&result)); } } } } /* Test returned values */ VARADD(I4,4,I4,2,I4,6); VARADD(I2,4,I2,2,I2,6); VARADD(I2,-13,I4,5,I4,-8); VARADD(I4,-13,I4,5,I4,-8); VARADD(I2,7,R4,0.5,R4,7.5); VARADD(R4,0.5,I4,5,R8,5.5); VARADD(R8,7.1,BOOL,0,R8,7.1); VARADD(BSTR,lbstr,I2,4,R8,16); VARADD(BSTR,lbstr,BOOL,1,R8,13); VARADD(BSTR,lbstr,R4,0.1,R8,12.1); VARADD(R4,0.2,BSTR,rbstr,R8,12.2); VARADD(DATE,2.25,I4,7,DATE,9.25); VARADD(DATE,1.25,R4,-1.7,DATE,-0.45); VARADD(UI1, UI1_MAX, UI1, UI1_MAX, I2, UI1_MAX + UI1_MAX); VARADD(I2, I2_MAX, I2, I2_MAX, I4, I2_MAX + I2_MAX); VARADD(I2, I2_MAX, I2, I2_MIN, I2, I2_MAX + I2_MIN); VARADD(I2, I2_MIN, I2, I2_MIN, I4, I2_MIN + I2_MIN); VARADD(I4, I4_MAX, I4, I4_MIN, I4, I4_MAX + I4_MIN); if (HAVE_OLEAUT32_I8) { VARADD(I4, I4_MAX, I4, I4_MAX, I8, (long long)I4_MAX + I4_MAX); VARADD(I4, I4_MIN, I4, I4_MIN, I8, (long long)I4_MIN + I4_MIN); } else { VARADD(I4, I4_MAX, I4, I4_MAX, R8, (double)I4_MAX + I4_MAX); VARADD(I4, I4_MIN, I4, I4_MIN, R8, (double)I4_MIN + I4_MIN); } VARADD(R4, R4_MAX, R4, R4_MAX, R8, (double)R4_MAX + R4_MAX); VARADD(R4, R4_MAX, R4, R4_MIN, R4, R4_MAX + R4_MIN); VARADD(R4, R4_MIN, R4, R4_MIN, R4, R4_MIN + R4_MIN); VARADD(R8, R8_MAX, R8, R8_MIN, R8, R8_MAX + R8_MIN); VARADD(R8, R8_MIN, R8, R8_MIN, R8, R8_MIN + R8_MIN); /* Manualy test BSTR + BSTR */ V_VT(&left) = VT_BSTR; V_BSTR(&left) = lbstr; V_VT(&right) = VT_BSTR; V_BSTR(&right) = rbstr; hres = VarAdd(&left, &right, &result); ok(hres == S_OK && V_VT(&result) == VT_BSTR, "VarAdd: expected coerced type VT_BSTR, got %s!\n'", vtstr(V_VT(&result))); hres = VarR8FromStr(V_BSTR(&result), 0, 0, &r); ok(hres == S_OK && EQ_DOUBLE(r, 1212), "VarAdd: BSTR value %f, expected %f\n", r, (double)1212); /* Manuly test some VT_CY and VT_DECIMAL variants */ V_VT(&cy) = VT_CY; hres = VarCyFromI4(4711, &V_CY(&cy)); ok(hres == S_OK, "VarCyFromI4 failed!\n"); V_VT(&dec) = VT_DECIMAL; hres = VarDecFromR8(-4.2, &V_DECIMAL(&dec)); ok(hres == S_OK, "VarDecFromR4 failed!\n"); memset(&left, 0, sizeof(left)); memset(&right, 0, sizeof(right)); V_VT(&left) = VT_I4; V_I4(&left) = -11; V_VT(&right) = VT_UI1; V_UI1(&right) = 9; hres = VarAdd(&cy, &right, &result); ok(hres == S_OK && V_VT(&result) == VT_CY, "VarAdd: expected coerced type VT_CY, got %s!\n'", vtstr(V_VT(&result))); hres = VarR8FromCy(V_CY(&result), &r); ok(hres == S_OK && EQ_DOUBLE(r, 4720), "VarAdd: CY value %f, expected %f\n", r, (double)4720); hres = VarAdd(&left, &dec, &result); ok(hres == S_OK && V_VT(&result) == VT_DECIMAL, "VarAdd: expected coerced type VT_DECIMAL, got %s!\n'", vtstr(V_VT(&result))); hres = VarR8FromDec(&V_DECIMAL(&result), &r); ok(hres == S_OK && EQ_DOUBLE(r, -15.2), "VarAdd: DECIMAL value %f, expected %f\n", r, (double)-15.2); } START_TEST(vartest) { hOleaut32 = LoadLibraryA("oleaut32.dll"); test_VariantInit(); test_VariantClear(); test_VariantCopy(); test_VariantCopyInd(); test_VarParseNumFromStr(); test_VarNumFromParseNum(); test_VarUdateFromDate(); test_VarDateFromUdate(); test_SystemTimeToVariantTime(); test_VariantTimeToSystemTime(); test_DosDateTimeToVariantTime(); test_VariantTimeToDosDateTime(); test_VarFormatNumber(); test_VarFormat(); test_VarAbs(); test_VarNot(); test_VarSub(); test_VarMod(); test_VarFix(); test_VarInt(); test_VarNeg(); test_VarRound(); test_VarXor(); test_VarOr(); test_VarEqv(); test_VarMul(); test_VarAdd(); }